The effect of linear infrastructures on habitat fragmentation · European Co-operation in the Field...
Transcript of The effect of linear infrastructures on habitat fragmentation · European Co-operation in the Field...
European Co-operation in the Field of Scientific andTechnical Research
COST 341
The effect of linear infrastructures
on habitat fragmentation
Hungarian State of the Art Report
European CommissionDirectorate General Transport
Commissioned by theTechnical and Information Services on National Roads (ÁKMI)
Compiled by theEnvironmental Management Institute
on the basis of co-operation between theNational Authority for Nature Conservation of the Ministry for Environment
and of theMinistry for Transport, Communications and Water Management
Compiled from the materials of the following authors:
Editor: Orsolya Pallag
Project manager: Ágnes Simonyi
Project co-ordinator: Angéla Kovács
Photo credits: Zoltán Alexay, Péter Farkas, Geleta & Geleta, Zsolt Kalotás,Tibor Seregélyes, Hortenzia Szombathy, József Zsidákovits
Consultants on behalf of thefor National Authority for Nature Conservation of the Ministry for Environment:
András Demeter, Gábor Duhay, Rozália Szekeres, Ödön Ráday
Revised by Tibor Seregélyes
Translated by Réka Aszalós, Réka Könczey and Gabriella Pászty
Published byTechnical and Information Services on National Roads (ÁKMI), Budapest, Hungary
June, 2000
Type-set Pars Ltd., Budapest
Botond BakóAttila BankovicsDénes BarthaTamás BergAndrás BidlóAttila CsemezSándor FaragóGábor KovácsAndrás KunViktor MárthaOttó MerklZsolt Molnár
Ferenc NémethOrsolya PallagAttila PellingerMiklós PukyLászló PásztorTibor SeregélyesÁgnes SimonyiHortenzia SzombathyGábor TakácsTibor TóthKatalin Török
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Table of Contents
Chapter 1. Introduction . . . . . . . . . . . . . . . . . . . . . 5Objectives of the IENE programme. . . . . . . . . . . . . . . . 5General information about COST 341 . . . . . . . . . . . . . . . 6
Chapter 2. Ecological concepts . . . . . . . . . . . . . . . . . . . 72.1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
2.2. Ecological networks . . . . . . . . . . . . . . . . . . . . . . . . . 7
2.3. Habitat fragmentation . . . . . . . . . . . . . . . . . . . . . . . . 8
2.4. Summary . . . . . . . . . . . . . . . . . . . . . . . 10Chapter 3. Effects of infrastructure on nature . . . . . . . . . . . . . . 11
3.1. Direct effects . . . . . . . . . . . . . . . . . . . . . . 113.1.1. Habitat loss and transformation . . . . . . . . . . . . . . 113.1.2. Disturbance (local pollution, fluctuations of water balance) . . . . . . 113.1.3. Effects on animals. . . . . . . . . . . . . . . . . . . 12
Chapter 4. National and European relationships, features. . . . . . . . . . . 154.1. Biogeographic description . . . . . . . . . . . . . . . . . . 15
4.1.1. Land-use history in the Carpathian Basin. . . . . . . . . . . . 154.1.2. Description of the main biogeographical zones of Hungary . . . . . . 16
4.2. Potential effects of infrastructure on the biota of Hungary . . . . . . . . 214.3. Overview of fragmentation due to different land-uses . . . . . . . . . 304.4. Administrative and legislative framework . . . . . . . . . . . . . 33
4.4.1. Environment and nature protection . . . . . . . . . . . . . 334.4.2. Administrative and legislative framework for traffic and transport . . . . 41
4.5. Land-use planning in relation to nature and landscape conservation and transport . 424.6. Summary . . . . . . . . . . . . . . . . . . . . . . . 44
Chapter 5. Habitat fragmentation due to existing transportation infrastructure . . . . 455.1. Introduction . . . . . . . . . . . . . . . . . . . . . . 455.2. Transportation network of Hungary . . . . . . . . . . . . . . . 45
5.2.1. Public roads . . . . . . . . . . . . . . . . . . . . 455.2.2. Railway . . . . . . . . . . . . . . . . . . . . . . 485.2.3. Waterways . . . . . . . . . . . . . . . . . . . . . 48
5.3. Effects of the existing transportation network on nature . . . . . . . . . 495.3.1. Habitat loss . . . . . . . . . . . . . . . . . . . . . 495.3.2. Disturbance. . . . . . . . . . . . . . . . . . . . . 505.3.3. Corridor function (The role of linear infrastructures in the invasion of species) 555.3.4. Fauna casualties . . . . . . . . . . . . . . . . . . . 575.3.5. Barrier effects . . . . . . . . . . . . . . . . . . . . 675.3.6. Overview of environmental bottlenecks . . . . . . . . . . . . 69
5.4. Summary . . . . . . . . . . . . . . . . . . . . . . . 73Chapter 6. Traffic safety in relation to animal casualties. . . . . . . . . . . 75Chapter 7. Compensation measures to reduce effects . . . . . . . . . . . 77
7.1. Introduction . . . . . . . . . . . . . . . . . . . . . . 777.2. Possibilities of avoiding habitat fragmentation . . . . . . . . . . . 777.3. Overview of mitigation measures . . . . . . . . . . . . . . . 807. 4. Overview of compensation measures . . . . . . . . . . . . . . 927.5. Maintenance aspects . . . . . . . . . . . . . . . . . . . 957.6. Evaluation and monitoring of the effectivity of measures . . . . . . . . 967.7. Summary . . . . . . . . . . . . . . . . . . . . . . . 96
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Chapter 8. Habitat fragmentation and future infrastructure development . . . . . 998.1. Introduction . . . . . . . . . . . . . . . . . . . . . . 998.2. Policies and strategies/trends . . . . . . . . . . . . . . . . . 1008.3. Indicators and indexes of fragmentation . . . . . . . . . . . . . 1068.4. Summary evaluation . . . . . . . . . . . . . . . . . . . 106
Chapter 9. Economic aspects – rentability of investment, prices,cost-benefit calculations, finance . . . . . . . . . . . . . . . . . 109
Chapter 10. Summary . . . . . . . . . . . . . . . . . . . . . 111
Literature sources . . . . . . . . . . . . . . . . . . . . . . 113
Chapter 1. Introduction
Local infrastructures of the late nineteenth century were self-supporting systems, operating onthe regional level, such as a county or an industrial region. These systems were connected withthe developmental centres of the wider environment and with the infrastructure systems be-yond the surrounding borders. Mezo- and microregions of forested mountains and drainedwetlands had been excluded from this infrastructure development. Due to their isolation, theseareas became peripheries in terms of economic geography, but at the same time, shelters ofbiodiversity.
The flora and the fauna of a region and the change of the diversity of species were highly deter-mined by the expanding urbanisation and the extension of the related infrastructural elements.Direct and indirect impacts of these improvements all decreased the area of natural andsemi-natural environment.
After the political transition of 1989, infrastructure systems underwent a rapid development.Chiefly the market conform improvements, such as the telephone network, gas supply, land-fills and the road system developed. Attention of experts observing the effect of investmentsand also that of politicians focused on the transformation of human environment (air- andnoise-pollution, road safety). In spite of the alerts of nature conservation experts, hardly anystudies were done on the effect of the altered environment on plant and animal communitiesand on their survival conditions.
On the occasion of nominating 1995 the “Year of European Nature Conservation” a confer-ence was held in The Netherlands, in September 1995. The fragmentation of habitats by linearinfrastructures was the main topic of the conference.
Linear infrastructures destroy “biologically active” surfaces and hinder the migration of spe-cies. The remaining habitat patches of limited extension may be too small for supporting thesurvival of some species. These phenomena all result in the decline of biodiversity.
The establishment of EECONET (European Ecological Network) was initiated by the Mem-ber States of European Community with the aim of establising a network of valuable habitats.Hungary joined the planning of the network in 1993 and the network was designed for thecountry.
The need of a new European programme Infra Eco Network (IENE) was expressed by the or-ganisers of the conference in ‘95. The programme aims to study the effect of infrastructure de-velopment on habitat fragmentation at a European level.
Objectives of the IENE programme
• stimulation of co-operation and the exchange of expertise,
• European integration of the conservation of natural values,
• elaboration of an action plan on European level,
• set the priorities for the solution of conflicts between nature conservation and infra-structure development,
• compilation of a European manual for mitigation measures.
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An EU supported scientific forum the COST (European COoperation in the Field of Scientificand Technical Research) provides the framework for the co-operative work. Hungary joinedthe COST in 1991.
COST is a multilateral European research-and-development cooperation forum in the field ofscientific and technical researches and provides the opportunity of mutually beneficial inte-gration of research programmes covering similar problems in different countries.
The present international project, initiated by the IENE, dealing with the fragmentation effectsof infrastructure networks, was launched in September 1998. The first countries to join wereHungary, The Netherlands, Romania, Spain, Sweden and Switzerland.
GENERAL INFORMATION ABOUT COST 341
Objectives
The main objective is to promote a safe and sustainable pan-European transport infrastructurethrough recommending mitigation measures and planning procedures with the aim of con-serving biodiversity and reducing accidents and animal road kills.
Duration of the project
4.5 years between September 1998 and July 2003
Deliverables
COST 341 project aims to demonstrate the current situation of habitat fragmentation causedby construction and use of the transportation networks in Europe, to gather the best practiceregarding methodologies, indicators, technical design and procedures for avoidance, mitiga-tion and compensation of adverse effects on nature in a handbook of best practice, to bring to-gether information on European expertise. To set up a database on existing literature and aglossary of terms used in the field of infrastructure and habitat fragmentation in on-line data-base is also an important part of the project. Therefore, there are three main products to be de-livered by COST 341: European State of Art Report, European Handbook and On-lineDatabase.
The present volume is the National Report of Hungary to the COST 341 project which summa-rises the status of habitat fragmentation in Hungary caused by linear infrastructures on thebase of researches regarding this topic.
COST 341
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Chapter 2. Ecological concepts
2.1. INTRODUCTION
The most fundamental, essential feature of the biosphere is diversity. Diversity is the basis foradaptation to the ever-changing conditions of life. Biodiversity is an independent qualitativecategory that cannot be compared or treated in relative terms. It is important in itself and for it-self. The concept of biodiversity includes the different levels of diversity, from the geneticlevel, as a basis for all evolutionary and selection processes, to the level of species or even hab-itats. So, even biodiversity is diverse and all parts of it are important.
The function of self-organising systems of nature suffers serious damage due to humanactivities. These all can lead to a rapid degradation and a decrease of amenity value. In the longrun, the accelerating decline of the self-sustaining ability of nature can lead to the transforma-tion of the system.
The determination of the smallest viable population is a fundamental issue. What is the small-est number (so-called extinction threshold) of individuals needed for survival? The answer isusually not known. According to our recent knowledge, in case of herbal plants a population of10.000 individuals can bear the genetic variability that is able to cope with stochastic environ-mental changes, and can keep the population alive in the long run. This is one of the reasonswhy the in situ conservation, as well as the control and the final blocking of fragmentation isessential.
Populations of species almost in all cases occur together with other species and this co-occur-rence (so-called co-existence) is far from stochastic. The generally accepted principle ofGauze states that populations with the same ecological requirements and tolerance character,due to the competition, cannot live together in the long run. Species with a wide range of toler-ance usually occur in several different communities. Appearance of weeds, for example, fol-lows human activity that alters competitive interactions. The invasive plants are usuallystress-tolerant, aggressive competitors. Due to their architecture, growth-form and strategy ofdispersal they can modify the structure and dominance order of stable communities.
The regulation of ecological systems can be tracked from the level of populations up to thelevel of the biosphere. This regulation ensures diversity that is manifested at all levels of livingsystems and supports the extremely high variability of living organisms.
Human being has a special, leading role in this system. The human being is the only speciesthat is able to hinder, control, eliminate and destroy other life forms around him. No othercomparable organism known from the billiard-year history of the biosphere. This fact alsosuggests that human strategy is probably not a long-term adaptive strategy in terms of evolu-tion.
2.2 ECOLOGICAL NETWORKS
Natural and semi-natural areas and habitats should not be considered as strictly divided islandsor “reserves”, but as unified and connecting systems. An ecological network is a coherent,functioning system, in which communication is active between natural habitats. Patches ofhabitats – with greater than a critical size – are the core areas. Their size is ideal in case theyprovide habitat and genetic reserve for the most possible populations among the given condi-tions. Communication between the core areas is realised by the so-called ecological corri-
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dors. Ecological corridors are linear, continuous habitats, or habitat-chains with smaller orgreater interruptions.
During the planning of the ecological network, the following main area-types were defined ac-cording to the system of the European Union Habitat Directive:
Core areas
Complex protection of biodiversity is a priority in these areas. The most suitable areas of pro-tection are the natural and semi-natural habitats with a size beyond a critical threshold, whichtherefore can preserve high diversity of species. Potential of a long-term protection and stabil-ity of the site are fundamental viewpoints during the core area selection.
Buffer zones
To ensure the protection and stability of core areas, they have to be surrounded by bufferzones. These areas should be also semi-natural habitats, or even slightly degraded areas suit-able for rehabilitation with adequate management.
Ecological corridors and stepping stones
(Stepping stones are habitat islands that enable the migration.)
The primary function of ecological corridors and stepping stones is:
• to provide connection between natural and semi-natural core areas,
• to ensure the natural migration and dispersal of species in a given region,
• to ensure the escape of species from the effect of unfavourable climate change,
• to support the gene-flow between the populations of a species living in different habitats.
2.3. HABITAT FRAGMENTATION
Environmental influences penetrate into the heart of habitats. The neutralisation of these ef-fects depends on the nature of the habitat. Furthermore, the size of the habitat and the parame-ters of the surrounding area are the main factors determining its stability in providing optimalconditions for populations. As a result, all habitats can be divided into an marginal-zone and acore area enclosed by the marginal-zone. Only the core area can provide long-term stability ofoptimal conditions for species. Even habitats exclusively under natural influences can be char-acterised by these zones. All roads and other linear infrastructure (electrical- and telephone ca-bles, water- and gas-pipes, canals) create edge-effect in a habitat.
The size of the edges along a linear infrastructure is determined by the strength of the effectcoming from the object and by the surrounding vegetation. In worst cases the total eliminationof the habitat can take place, or if the core area is also affected, it may fall apart to smaller areasbeing no longer able to function as a core area. For example the flora and fauna of road edgesare constantly impoverished by the traffic and by the road itself and consequently the core ar-eas are damaged as well. Roads and their traffic can lead to the total isolation of populations:these objects are impenetrable barriers, especially for those species that can move just withintheir original habitat.
Species character change can be a result of limited gene-flow between its populations. Linearinfrastructures, such as forest clearings can separate or eliminate core areas by increasing theedge-effect. Isolation of core areas can lead to the cessation of the gene-flow. Barriers that cutecological corridors have primary importance. Corridors provide – continuously, or in habitat
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island systems (stepping stones) – conditions for dispersal, reproduction and migration of spe-cies (see Figure 2.1.). Spatial and temporal dimensions of these movements follow an individ-ual pattern in case of each species. It can be limited, for example, only to the period of breedingor foraging. The success of these movements is guaranteed only if the species can transitthrough the barriers between the habitats. (While birds and flying insects can migrate long dis-tances, smaller animals with limited ability of dispersal “migrate” just few metres per year.Plants show similar pattern: the distance of dispersal of small and wind-transported seeds ismuch greater than that of the large seeds. Great and heavy propagules can perform quick dis-persal in case of carriage by birds or by water, but generally these seeds have less “effective” –for example ants – or no transporter. The dispersal of these plants is extremely slow.)
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Figure 2.1. Scheme of ecological corridors
Habitat fragmentation is the division of habitats or habitat mosaics by territory loss. It is notidentical with the natural isolation of some communities, generally of small area, such as fensor rocky grasslands. ‘Dispersion’ is a probably better, but still not completely accurate term inthis case.
The conceptual interpretation of fragmentation is not coherent. Even professional papers con-fuse the two, following situations:
• three patches of oak forest with the size of 10, 100, and 1000 ha is controlled by an abioticbackground variable,
• due to the effect of roads and other linear infrastructures, out of the original 3000 ha oakforest three patches remained with the size of 10, 100, and 1000 ha.
In the first case, species are adapted to the situation at an evolutionary time-scale, while theyshould adapt within few decades in the second case. In the first case, ecological corridors arenot needed, hence originally separated habitats should not be linked. In the second case, thedistances between patches cause total isolation for several species, ecological corridors haveto be installed.
2.4. SUMMARY
Some of those principles of ecology were described above which may deserve attention inchoosing the route and designing roads. Under the existing technological potential a road canbe constructed practically anywhere. This possibility frequently induces designers and deci-sion makers to suppose that after resolving the technical problems nature can also be “sub-dued”. Rare and protected plants are in most cases unsuccessfully transplanted if their habitatconflicts with the route design. To wait for animals to become accustomed to environmentalconstraints caused by investments is hopeless, they rather escape or die out. At the same timesome other common stress tolerating plant and animal species become tolerant abundant. If wewant to preserve biodiversity we have to acknowledge ecological principles and rules. By de-signing and realising ecological networks and other mitigating measures the adverse effects ofinfrastructure can be decreased significantly.
However, details for these measures (for example type of mitigation, minimum size of habitat)can only be given on the basis of thorough knowledge of nature.
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Chapter 3. Effects of infrastructure on nature
3.1. DIRECT EFFECTS
Since data are only available for the effects of traffic, especially road traffic, hereafter underthe term infrastructural effects, the effects of road traffic will be meant, unless otherwisestated.
The infrastructure of transport and especially the improvement of the road system can have ahighly adverse effect on biodiversity. The harmful effect of operating factors only manifest inthe long run. At the beginning of the process, the direct cumulative or synergetic effects arehardly recognisable. Only later they do become evident, when their handling gets much morecomplicated, or the detrimental processes have become irreversible.
3.1.1. Habitat loss and transformation
Habitat loss is one of the most striking effects. It is partly caused by roads themselves, partlyby other linking establishments (petrol stations, rest areas, etc.) along the roads. A road lead-ing across a natural countryside can have a spectacular “environment destroying” impression,but the auxiliary effect of additional roads in an already fragmented landscape is less striking.
Roadside verges are of outstanding importance. Their optimal width is obviously species de-pendent (20–500 metres) and gives a different value for the red deer or the beech. Semi-naturaledge habitats often enrich the local flora and fauna enabling the emergence of new species.(Some plants and small animals – often rare and protected species – definitely rely on suchedges.) However, the creation of edges and the resulting enrichment caused by linear infra-structures is often disadvantageous, because the road decreases the area of the intact innerparts of stands. The roads often affect the habitats of the most endangered species in the innerparts of stands. (Asplenium fontaneum became extinct from its only habitat in Hungary thisway. This rock-dwelling fern fell victim to road constructions in the Fáni Valley.) Further-more, the majority of new plant species gaining a foothold along linear infrastructures areruderal or disturbance tolerant. Roadside verges act as ecological corridors for their propaga-tion.
3.1.2. Disturbance (local pollution, fluctuations of water balance)
Effects of building up
Owing to building up, soil loses its original state and several of its features change (e.g.: mois-ture content) and becomes deprived of its properties favourable for plants. The parameters ofthe filter layer change (ground water becomes polluted more easily) and new land formationsare created altering natural run-off conditions.
The load along roads leads to the compaction of soils. As a result, the volume of pores de-creases (especially that of large pores) causing the decline of aeration and the change ofheat-balance. The mobility of soil fauna also decreases, microbe activity and nutrient-balancechange and the water permeability of soil decreases.
Effects of drainage and waterlogging
Drain canals built along roads together with run-off from roads permanently alter the waterbalance of soils. The area of the affected region greatly depends on the relief and the orienta-tion of drain canals. The change is twofold: due to run-off the moisture content of soil de-
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creases in some localities, while it increases caused by the collection of water in other places.While on average 15% of the precipitation runs off the surface of areas not built up, the ratiocan be as high as 60-80% in built-up areas.
During road constructions the impermeable soil layers may be penetrated, causing the lower-ing of the watertable, which principally affects the composition of plant communities. In ex-treme case this can lead to the increased ratio of drought tolerant species and thus thereplacement of the original vegetation. All these changes substantially influence the composi-tion of the fauna (e.g.: the presence of pollinators) as well.
Effects of pollution originating from transport
Various substances are emited to the air with traffic. A portion of these quickly deposits ontoroads and the surrounding ground. Pollution along roads is the highest within the first fewmetres and becomes relatively low at a distance of 20 metres, although a measurable amountof whirled dust can get as far as 1000 metres from the road. The amount and spread of dust ba-sically depends on the soil type, vegetation, relief, the speed of vehicles, exposure and mois-ture conditions. Large amount of dust can deposit on the vegetation along roads.
Acid load
One of the most important impacts of transport – and therefore roads – on the environment isthat of various acids (Nunné 1994). Among them nitric acid and nitrous acid are the most fun-damental, which deposit to the ground surface from various nitrogen-oxides (NOx) from theatmosphere. Owing to acidification, the species composition of soil microorganisms changes– e.g.: the ratio of fungi increases at the expense of bacteria – and some organisms disappear. Itis partly soil acidification – and therefore transport – that causes the phenomenon called “newtype of woodland deterioration” which affects most woodlands in Europe.
Effects of salts
Deicing salts are applied to the majority of our roads in winter to ensure a steady traffic. Theamount of salt spread this way can be considerable (0.8–1.2 kg/m² by public road maintenanceand handling rules). Consequently, a great amount of NaCl or MgCl2 can get into the soil. Theincreased amount of Na in the soil replaces Ca and Mg on the surface of the adsorption com-plex. Sodium ions have large hydrate coatings, which can cause the peptisation of soil and theloss of drainage, which ultimately increases the hazard of erosion.
Salt accumulation along roads can have a drastic impact on the quality of vegetation. The de-cay of town tree species (e.g.: horse-chestnut, plane) along the roads of Budapest is a commonphenomenon. The impact is partly direct, partly indirect: weakened specimens are attacked byparasites. The adverse effects of salting can be apparent in the case of natural vegetation aswell, although not much is known about them.
3.1.3. Effects on animals
The influence of various types of roads on animals largely depends on the quality of road sur-face (earth, asphalt, concrete), its width and the temporal and spatial distribution of trafficintensity. These effects principally affect arthropods, amphibians, reptiles, birds, and mam-mals.
The degrading effects may be direct, e.g.: habitat segregation, road kills, pollution, modifica-tion of migration route or indirect, e.g.: disturbance, pollution, and their consequences.Feathered and furry animals are relatively easy to identify even several days after their death.
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In the case of other taxa (especially arthropods, amphibians, reptiles) identification is difficultin the lack of identification marks. As a result, the number of run-over animals is usually sig-nificantly underestimated (Hels 1999) and the assessment of damage done to their populationsis complicated if not impossible. The alteration of population structure, however, has a directinfluence on the composition of a given community and the temporal and spatial changes ofother plant and/or animal populations.
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Chapter 4. National and European relationships, features
4.1. BIOGEOGRAPHIC DESCRIPTION
4.1.1. Land-use history in the Carpathian Basin
Man has been present in Eurasia for hundreds of thousands of years. At the beginning, themain source of living was hunting and gathering which did not have a significant effect on thenatural environment. During the late Ice Age, the Palaeolithic, about 4000 people, in theMesolithic about 16–17,000 people must have inhabited the 325,500 km2 area of the Car-pathian Basin. The warming of the climate contributed to the population growth.
Substantial land-use – animal husbandry and agriculture – must have begun in the Neolithic,approximately the second half of the sixth millennium BC. This was the so-called Atlantic erain vegetation history, when the climatic steppes of the Great Hungarian Plain became forested,mainly with oak. This process is likely to have been influenced by human deforestation andfarming. In the second-third part of the Neolithic the first dwelling hillocks (“tell” in Hungar-ian) appeared indicating the gradual conversion of the landscape. As food production started,population boom resulted in the exploitation, transformation and destruction of the naturalvegetation.
In the subboreal era of vegetation history the climate became slightly cooler causing thespread of beech. In the second half of the subboreal era, the rotation system of farming andshepherding became widespread, accompanied by substantial deforestation. Beside bronzemaking and metallurgy that started to spread from the second millennium BC, tumulus(“kurgán” or “kunhalom” in Hungarian), earthwork and mound building, pottery and crema-tion burials also required a lot of wood. Later, as the major part of the Great Hungarian Plainbecame inhabited, villages were also built in the closed oak zone of the mountain ranges. Ac-cording to pollen analytical studies the ratio of the pollens of cereals and segetal weeds greatlyincreased from this time on. Based on these results, the first big wave of deforestation is as-sumed to have started in the Iron Age, second millennium BC. Owing to the fast developmentof farming tools huge areas were turned into arable fields.
At the beginning of our era, Romans arriving at the Carpathian Basin found and broughthighly developed (mainly Celtic) agricultural technologies. The Empire also served as an im-mense market for the goods originating form here. Large farms became widespread at thistime and partly survived even after the disintegration of the Province. Nomadic and othertribes (Alans, Sarmats, later Huns and Avars, finally Hungarians) that arrived at the GreatHungarian Plain at this time or later, found settled communities with long plant cultivation tra-ditions. The immigrants, after settling down, dealt with animal husbandry and farming.
The early Middle Age was characterised by further deforestation. Beside house building, char-coal-burning and the firewood supply of the ever increasing population also required largeamounts of wood. The last great deforestation of the Great Hungarian Plain, which resulted ina landscape similar to that of nowadays, must have taken place in the Turkish era. Owing tolong lasting wars and the spread of animal grazing vast territories became treeless steppes. Thesubsequent extensive grazing could have maintained the steppes.
In the middle of the last century, demand for arable land increased thanks to cereal prosperity,so practically all loess steppes were tilled. (Fertile loess fields were ploughed and cultivated asearly as the 11–12th century AD under the reign of the Árpád dynasty kings.) As a conse-
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quence of the canalisation of rivers and drainage in the 19th century, evaporation exceeded theamount of precipitation by far resulting in the crystallization of salt on the soil surface and theincrease of the area of salt marshes. Later, as grazing became more intensive and fodder wasgrown in ever larger quantities, the fragmentation of grasslands was further enhanced.
The present labdscape of the Carpathian Basin was formed as a result of the processes brieflydescribed above. The development of the actual vegetation has been affected by human activi-ties since the Atlantic era. Therefore, the early and present role of man in the formation of thelandscape should always be taken into consideration when designing and executing manage-ment, research and nature conservation works.
4.1.2. Description of the main biogeographical zones of Hungary
Hungary is situated mainly in the zone of European deciduous woodlands. The Great Hungar-ian Plain, however, belongs to another climatic vegetation zone, being the westernmost exten-sion of the Eastern European mosaic of woodlands and steppes, the so-called forest steppe. Thewestern boundary of the country – owing to alpine climatic effects – belongs to the region ofMiddle European mixed coniferous woodlands.
Natural vegetation is the original vegetation of a region, evolved without any human influ-ence. Potential vegetation would develop in the absence of man from now on. Actual vegeta-tion refers to the vegetation found presently. This, mainly secondary vegetation in most of theCarpathian Basin is only partly considered (mainly in the mountain ranges) semi-natural ornatural.
The discussions below are based on the results of floristic and phytocoenological researchesdone primarily in Hungary. The potential vegetation of destroyed areas can be inferred fromthe bedrock, relief, local climate and the present semi-natural vegetation types. (This methodwas applied when creating the potential vegetation map of Hungary.) Outputs of the examina-tions of the actual vegetation may be applied to the natural vegetation, but only with care.
Great Hungarian Plain region
Its complete area, covered by Pleistocene and Holocene wind and river sediment, belongs tothe forest steppe zone. Today it is mostly arable land with small patches of the remaining natu-ral vegetation. Larger rivers are accompanied by enormous gallery forests, the areas betweenrivers are composed of the mosaic of sand dunes and loess and salt steppes. The last remnantsof the once extensive marshes still exist locally with some remarkable glacial relict species.
Owing to its relative isolation – the Great Hungarian Plain is surrounded by medium and highmountains – the number of endemic plant species (and subspecies) is relatively high (about20). Some of them have become rare due to human activities and there are plenty of threatenedspecies living at the limit of their ecological requirements.
Some endemic species (most also threatened) are as follows: Suaeda pannonica, Limonium
gmelinii subsp. hungaricum, Dianthus serotinus subsp. serotinus, Festuca vaginata, Dianthus
diutinus, Adonis x hybrida syn.: A. transsilvanica, Pulsatilla pratensis subsp. hungarica, As-
ter sedifolius, Sedum urvillei subsp. hillebrandtii, Epipactis bugacensis and other Epipactis
species, Linum hirsutum subsp. glabrescens, Plantago schwarzenbergiana, Onosma arenaria
subsp. tuberculata, Armoracia macrocarpa, Cirsium brachycephalum, Tragopogon flocco-
sus, Colchicum arenarium.
16
COST 341
Noteworthy species (most of them have a continental or Pontic-Pannonian area) are: Cra-
taegus nigra, Vitis vinifera subsp. sylvestris, Crambe tataria, Urtica kioviensis, Salvia nutans,
Plantago maxima, Potentilla palustris syn.: Comarum palustre, Trollius europaeus, Bulbo-
codium vernum, Pulsatilla patens, Rumex pseudonatronatus, Astragalus exscapus, Astra-
galus dasyanthus, etc.
Northern Mountain Range region
The foothill zone of the inner region of the Carpathian Mountains is made up of mainly volca-nic rocks (especially andesite) and partly limestone. The warm southern slopes are covered bythermophilous Pannonic vegetation at lower elevations and dry oak (chiefly Turkey oak)woodlands over 600 m. Above this region oak-hornbeam woodlands, higher above collinebeech woodlands are found. True montane beech woodlands are rare in Hungary only presentover 900 m of elevation.
The number of endemic species – partly common with those of the Carpathian Mountains –is relatively high: Cardamine glanduligera syn.: Dentaria glandulosa, Thlaspi kovatsii subsp.schudichii, Dianthus praecox subsp. lumnitzeri, Onosma tornensis, Minuartia hirsuta subsp.frutescens, Sesleria heufleriana subsp. hungarica, Ferula sadleriana, Poa pannonica subsp.scabra, Erysimum wittmannii syn.: E. pallidiflorum, Hesperis matronalis subsp. nivea syn.:
H. m. subsp. vrabelyiana, Thlaspi jankae, Helleborus purpurascens, Pulsatilla pratensis
subsp. zimmermannii, Carduus collinus.
The number of protected and endangered species is very high, only some are listed here:Lonicera nigra, Matteuccia struthiopteris, Aster oleifolius, Dracocephalum austriacum, Dra-
cocephalum ruyschiana, Ribes alpinum, Allium victorialis, Clematis alpina, Micromeria
thymifolia syn.: Calamintha th., Dryopteris cristata, Physospermum cornubiense syn.: Danaa
cornubiensis, Viola biflora, etc.
17
Chapter 4
Figure 4.1.2.1. Alkaline steppe in the Hortobágy National Park.
Transdanubian Mountain Range region
This block mountain is composed of sedimentary rocks (limestone, Triassic dolomite, sand-stone) in the major part, and volcanic rocks in the minor part. It is characterised by a strongsubmeridional (Submediterranean with a dry summer) climatic effect. The surface weatheringof sedimentary rocks favours the establishment of thermophilous and rock vegetation and thesurvival of glacial relicts on the northern slopes. Turkey oak – sessile oak woodlands arefound on deep soils, while shallow soils are covered by closed thermophilous oak woodlands,scrublands and rock grasslands. Substantial beech woodlands are only found in the Bakonymountains or extrazonally, depending on the microclimate (in valleys, on northern slopes).Dolomite bedrock is of great importance for the flora, hosting several specialist and endemicspecies. The majority of glacial relicts is also found on the northern slopes of dolomite ravines.
The number of endemic species is relatively high (around 20), including plants that have onlyone or few populations in the world: Linum dolomiticum, Pyrus magyarica, Vincetoxicum
pannonicum, Sesleria sadleriana, Primula auricula subsp. hungarica, Knautia kitaibelii
subsp. tomentella, Achillea × horanszkyi.
Additional endemic and subendemic species are: Seseli leucospermum, Dianthus serotinus
subsp. regis-stephani, many Sorbus minor species, Draba lasiocarpa, Inula oculus-christi,etc.
There are a lot of protected, endangered or relict species, e.g.: Primula farinosa, Allium
victorialis, Dryopteris cristata, Carduus crassifolius subsp. glaucus, Scabiosa canescens,
Sternbergia colchiciflora, Doronicum hungaricum, Aethionema saxatile, etc.
18
COST 341
Figure 4.1.2.2. Pioneer rocky vegetation on the vulcanic rocks of the Mt. Füzér (ZemplénMts, NE Hungary).
Southern Transdanubian region
The climatic effect of the Balkans is getting stronger towards the south. There is a gradualtransition towards the Illyrian (Western Balkan) flora domain and the Balkan character of thevegetation increases to the south of the Lake Balaton. The bedrock is composed of basic andacid sand, loess and sedimentary rocks (especially limestone, but also sandstone and dolo-mite). Lowlands and rolling areas that receive a lot of precipitation are covered by beech andoak-hornbeam woodlands; drier areas host pedunculate oak and Turkey oak – sessile oakwoodlands. On the southern slopes of the Villányi and Mecsek mountains thermophilousPannonic-Balkan grasslands and woodlands are found, beech and oak-hornbeam woodlandsare only present on the northern slopes.
Endemic species are: Colchicum hungaricum, Paeonia officinalis subsp. banatica, Festuca
dalmatica var. pannonica, Vincetoxicum pannonicum.
The number of species of southern character is outstandingly high (over 50), most are endan-gered, protected and subendemic with a Submediterranean or Pannonic-Balkan area: Vicia
oroboides, Teesdalia nudicaulis, Digitalis ferruginea, Lamium orvala, Cardamine trifolia
syn.: Dentaria t., Lathyrus venetus, Anemone trifolia, Peucedanum verticillare, Inula spiraei-
folia, Orchis simia, Ranunculus psilostachys, Orobanche ramosa subsp. nana, Trigonella
gladiata, Doronicum orientale, Asperula taurina, etc. Some extremely rare and remarkablespecies are also found in the fens of the region, e.g.: Caldesia parnassifolia, Aldrovanda
vesiculosa, Osmunda regalis.
19
Chapter 4
Figure 4.1.2.4. Forest-steppe vegetation, patches of calcareous grasslands and xerothermicoak woodlands on dolomitic rocks in the Bakony Mountains (Transdanubian MountainRange).
Western Transdanubian region
The climate is wet and cool because of the proximity of the Alps. The bedrock is principallyacid metamorphic crystalline rock (schist) with some sand and clay and a minor amount of ba-sic sedimentary rocks. Pannonic xerothermic vegetation is limited to small areas, the charac-teristic vegetation being rich in submontane and boreal elements. Scots pine woodlands mixedwith oak, beech woodlands and oak-hornbeam woodlands reach large extensions.
Endemic species are more or less absent from this region (e.g.: Daphne cneorum subsp.arbusculoides). The rare alpine or montane elements found exclusively here in Hungary aremuch more significant, some of them being highly sensitive and endangered: Goodyera
repens, Chimaphila umbellata, Rhynchospora alba (extinct), Matteuccia struthiopteris, Vicia
oroboides, Moneses uniflora, Tephroseris aurantiaca syn.: Senecio aurantiacus, Arnica mon-
tana, Crocus vernus subsp. albiflorus, Alnus viridis, Thlaspi goesingense, Thlaspi alpestre,
Globularia cordifolia, Pinguicula vulgaris, Buphthalmum salicifolium, Gentiana asclepia-
dea, etc.
20
COST 341
Figure 4.1.2.5. Paeonia officinalis subsp. banatica an endemic species of the Mecsek Mts(Southern Transdanubian region).
4.2. POTENTIAL EFFECTS OF INFRASTRUCTURE ON THE BIOTA OF HUNGARY
Objectives, definitions and the explanation of evaluation categories
In this chapter the impact of roads and other linear infrastructures on the vegetation are as-sessed. Since no explicit research data are available, the following approaches were used forthe assessment:
1. The characteristics of habitats were examined to estimate their susceptibility to fragmenta-tion;
2. The intensity of the effects of fragmentation was evaluated for all possible influences.
The most characteristic and frequent habitats were studied among the natural, semi-naturaland cultural habitats of the country (Tables 4.2.1. and 4.2.2.). The list of habitats was compiledon the basis of the General Hungarian Habitat Classification System (Á-NÉR, Fekete et al.
1997, see also for habitat codes in Tables 4.2.1. and 4.2.2.) and the Red Data Book (Borhidi &Sánta 1999).
Habitat characteristics
Typical stand size (diameter) – Correlates with the chance of a given habitat to be hit by roads.Potential values (in metres) are: 10, 100, 1000, over 1000 metres.
Frequency of natural disturbance – The frequency of natural disturbances (e.g.: flooding,grazing, erosion) can play an important role in the sensitivity of habitats to anthropogenic dis-turbances. Potential values are: several per year, once per year, several per decade.
Longevity of dominant species – The average maximal age of the dominant species. It indi-cates the time scale of the dynamics of the habitat. Potential values are: 1, 10, 100, over 100years.
21
Chapter 4
Figure 4.1.2.6. Gentiana asclepiadea a rare species occurring in western Hungary.
22
COST 341
Ta
ble
4.2
.1.
Hab
itat
char
acte
rist
ics
and
stat
eo
far
to
ffr
agm
enta
tio
nin
Hu
ng
ary
Habitatcharacteristics
Submergedvegetation(A1–A5)
Reeds(B1–B3)
Sedges(B4–B5)
Saltmarshes(B6)
MiresC1–C3)
Fens(D1–D2)
Tallgrassmeadows(D3–D5)
Collineandmountanesemi-dry
grasslands(E1–E5)
Salinesteppes(F1–F3)
Salineswards(F4–F5)
Opensandygrasslands(G1)
Rockgrasslands(G2,G3,H1)
Slopesteppesandsecondary
meadows(H3,H4)
Loessandsandsteppes(H5)
Fen-woodlands(J1,J2)
Willowshrubsandforests(J3,J4)
Typic
alst
and
size
(dia
met
er
inm
)
10–
100
100–
1000
10–100
100
10–100
100–
1000
10–1000
100–
1000
Over
1000
10–100
100–1000
10–100
100
10–100
100
10–100
Fre
quen
cyof
nat
ura
ld
istu
r-
ban
ces
Once
per
yea
r–
sever
alper
dec
ade
Once
per
yea
r
–once
per
de-
cade
Once
per
yea
r
–once
per
de-
cade
Once
per
yea
r
–once
per
de-
cade
Once
per
de-
cade
Sev
eral
per
de-
cade
Once
per
yea
r–
once
per
dec
ade
Once
per
de-
cade
Once
per
yea
r
–once
per
de-
cade
Once
per
yea
r
–se
v-
eral
per
dec
ade
Once
per
yea
r–
once
per
dec
ade
Once
per
yea
r–
once
per
dec
ade
Once
per
dec
ade
Once
per
dec
ade
Once
per
yea
r
Sev
eral
per
yea
r
Longev
ity
of
do
min
ant
spe-
cies
1–10
10–100
10–100
10–100
10–100
100
100
10–100
1–100
1–10
1–10
1–100
10–100
10–100
100
–
over
100
1–100
Susc
epti
bil
ity
toed
ge
effe
ctm
ediu
mhig
hli
ttle
litt
lehig
hhig
hhig
hm
ediu
mli
ttle
litt
leli
ttle
litt
lem
ediu
mm
ediu
mhig
hm
ediu
m
Res
ilie
nce
hig
hhig
hli
ttle
–
med
ium
hig
hli
ttle
me-
diu
mm
ediu
mm
ediu
mhig
hhig
hhig
hhig
hli
ttle
litt
lem
ediu
mhig
h
Geo
gra
phic
al
dis
trib
uti
on
wid
erw
ider
wid
er
Pan
no-
nic
–B
al
kan
–
Ponti
c
wid
erw
ider
Pan
nonic
–B
al-
kan
–P
on
-
tic,
wid
er
wid
er
(sub)e
n-
dem
ic
Pan
no-
nic
–B
al
kan
–
Ponti
c
(sub)e
n
dem
ic
(sub)e
n-
dem
ic
Pan
nonic
–B
al-
kan
–P
on-
tic
Pan
no-
nic
–B
al
kan
–
Ponti
c
Pan
nonic
–B
al-
kan
–P
on-
tic
wid
erw
ider
23
Chapter 4
Sta
teof
the
arto
ffr
agm
enta
tion
inH
unga
ry(T
able
4.2.
1.co
ntin
ued)
Habitatcharacteristics
Submergedvegetation(A1–A5)
Reeds(B1–B3)
Sedges(B4–B5)
Saltmarshes(B6)
MiresC1–C3)
Fens(D1–D2)
Tallgrassmeadows(D3–D5)
Collineandmountanesemi-drygrasslands(E1–E5)
Salinesteppes(F1–F3)
Salineswards(F4–F5)
Opensandygrasslands(G1)
Rockgrasslands(G2,G3,H1)
Slopesteppesandsecondarymeadows(H3,H4)
Loessandsandsteppes(H5)
Fen-woodlands(J1,J2)
Willowshrubsandforests(J3,J4)
Dis
trib
utio
nin
Hun
gary
••
••
••
••
••
••
••
••
••
••
••
••
••
••
•
Deg
ree
ofha
bi-
tat l
oss
••
••
••
••
••
••
••
••
••
••
••
••
••
••
••
•
Deg
ree
offr
ag-
men
tati
on•
••
••
••
••
••
••
••
••
••
••
••
••
••
Suc
cess
ofin
vado
rsal
ong
corr
idor
s•
••
••
••
••
••
••
••
••
••
••
••
••
••
••
Rol
eof
corr
i-do
rsin
the
sec-
onda
ryfo
rmat
ion
ofha
bita
ts
••
••
••
••
••
••
••
••
••
••
••
••
Pos
sibi
lity
ofpo
llut
ion
••
••
••
••
••
••
••
••
••
••
••
••
••
••
••
••
Pos
sibi
lity
ofhi
drol
ogic
alch
ange
••
••
••
••
••
••
••
••
••
••
••
••
••
••
••
••
••
••
Enh
ance
men
t of
eros
ion
••
••
••
••
••
••
••
••
••
••
••
Sus
cept
ibil
ity
ofha
bita
tsto
frag
-m
enta
tion
••
••
••
••
••
••
••
••
••
••
••
••
••
••
•
24
COST 341
Tab
le4.2
.2.
Hab
itat
char
acte
rist
ics
and
stat
eof
art o
ffr
agm
enta
tion
inH
unga
ry
Habitatcharacteristics
Riverineoak-elm-ashandriverineash-alderwoodlands(J5,J6)
Pannonicoak-hornbeamwoodlands(K2)
Pannonicneutralcollineandmontanebeechwoodlands(K5)
WesternandIllyrianbeechandoak-hornbeamwoodlands(K3,K4)
Ravine,slopeandacidwoodlands,andwoodlandsonrocks(K6,K7,L3,L4)
Closedtermophilousoakwoodlandsandturkeyoak-sessileoakwoodlands(L1,L2)
Whiteoakshrubwoodlands(M1)
Steppeoakwoodlands(M2-M4)
Poplar-junipersteppewoodlands(M5)
AcidScotspinewoodlands(N1)
SecondaryanddegradedgrasslandsontheGreatHungarianPlain(O5,O6,O11,O12)
Secondaryanddegradedcollineandmontanegrasslands(O5,O6,O11,O12)
Grasslandswithspontaneouslycolonisingtreesandshrubs(P2)
Blacklocustandhybridpoplarplantations(S1,S2)
BlackandScotspineplantation(S4)
Typ
ical
stan
dsi
ze(d
iam
eter
inm
)
100–
1000
Ove
r10
00O
ver
1000
Ove
r10
0010
–100
Ove
r10
0010
0–10
0010
–100
010
0–10
0010
0–10
00,
over
1000
100–
1000
,ov
er10
00
100–
1000
,ov
er10
00
10–1
000
100–
1000
,ov
er10
00
100–
1000
,ov
er10
00
Fre
quen
cyof
natu
ral d
istu
r-ba
nces
Onc
epe
rye
ar–
once
per
deca
de
Sev
eral
per
de-
cade
Sev
eral
per
de-
cade
Sev
eral
per
de-
cade
Onc
epe
rye
ar–
once
per
deca
de
Sev
eral
per
de-
cade
Onc
epe
rye
ar–
once
per
deca
de
Onc
epe
rde
cade
Onc
epe
rye
ar–
once
per
de-
cade
Sev
eral
per
deca
de
Sev
eral
per
year
–de
cade
s
Sev
eral
per
year
–de
-ca
des
Onc
epe
rye
ar–
once
per
deca
de
Onc
epe
rye
ar–
once
per
deca
de
Onc
epe
rye
ar–
once
per
deca
de
Lon
gevi
tyof
dom
inan
t spe
-ci
es
100,
over
100
100,
over
100
Ove
r10
0O
ver
100
100,
over
100
100,
over
100
100,
over
100
100,
over
100
10–1
0010
0,ov
er10
01–
100
1–10
010
–100
1010
Sus
cept
ibil
ity
toed
geef
fect
high
med
ium
med
ium
med
ium
med
ium
me-
dium
litt
lem
ediu
mli
ttle
med
ium
litt
le–
high
litt
le–
high
litt
leli
ttle
litt
le
Res
ilie
nce
litt
lem
ediu
mhi
ghhi
ghhi
ghm
e-di
umm
ediu
mli
ttle
high
med
ium
high
–m
ediu
mm
ediu
mhi
ghli
ttle
litt
le
Geo
grap
hica
ldi
stri
buti
onw
ider
wid
erw
ider
wid
er
(Sub
)en-
dem
ic–
Pan
no-
nic–
Bal
-ka
n–P
onti
c
Pan
no-
nic–
Bal
kan–
Pon
tic
Pan
noni
c–B
al-
kan–
Pon
-ti
c
Pan
no-
nic–
Bal
-ka
n–P
on-
tic
(sub
)en-
dem
icw
ider
wid
erw
ider
wid
erw
ider
wid
er
25
Chapter 4
Sta
teof
the
arto
ffr
agm
enta
tion
inH
unga
ry(T
able
4.2.
2.co
ntin
ued)
Habitatcharacteristics
Riverineoak-elm-ashandriverineash-alderwoodlands(J5,J6)
Pannonicoak-hornbeamwoodlands(K2)
Pannonicneutralcollineandmontanebeechwoodlands(K5)
WesternandIllyrianbeechandoak-hornbeamwoodlands(K3,K4)
Ravine,slopeandacidwoodlands,andwoodlandsonrocks(K6,K7,L3,L4)
Closedtermophilousoakwoodlandsandturkeyoak-sessileoakwoodlands(L1,L2)
Whiteoakshrubwoodlands(M1)
Steppeoakwoodlands(M2-M4)
Poplar-junipersteppewoodlands(M5)
AcidScotspinewoodlands(N1)
SecondaryanddegradedgrasslandsontheGreatHungarianPlain(O5,O6,O11,O12)
Secondaryanddegradedcollineandmontanegrasslands(O5,O6,O11,O12)
Grasslandswithspontaneouslycolonisingtreesandshrubs(P2)
Blacklocustandhybridpoplarplantations(S1,S2)
BlackandScotspineplantation(S4)
Dis
trib
utio
nin
Hun
gary
••
••
••
••
••
••
••
••
••
••
••
••
••
••
••
••
•
Deg
ree
ofha
bi-
tat l
oss
••
••
••
••
••
••
••
••
••
••
••
•
Deg
ree
offr
ag-
men
tati
on•
••
••
••
••
••
••
••
••
••
••
••
••
••
Suc
cess
ofin
vado
rsal
ong
corr
idor
s•
••
••
••
••
••
••
••
••
••
••
••
••
Rol
eof
corr
i-do
rsin
the
sec-
onda
ryfo
rmat
ion
ofha
bita
ts
••
••
••
••
••
• •
••
••
••
••
Pos
sibi
lity
ofpo
llut
ion
••
••
••
••
••
••
••
••
••
Pos
sibi
lity
ofhi
drol
ogic
alch
ange
••
••
••
••
••–
••
••
••
••
••
••
••
Enh
ance
men
t of
eros
ion
••
••
••
••
••
••
••
••
••–
••
••
••
•
Sus
cept
ibil
ity
ofha
bita
tsto
frag
-m
enta
tion
••
••
••
••
••
••
••
••
••
••
•
Susceptibility to edge effect – The changes taking place in the margin of a habitat when crossedby a road. Potential values are: little, medium, high.
Resilience – The ability of a given habitat to return to or near its original state, following a ma-jor disturbance. Potential values are: little, medium, high.
Geographical distribution – The global distribution of a habitat appraised at three scales. Po-tential values are: (sub)endemic, Pannonic–Balkan–Pontic, wider.
Distribution in Hungary – An estimated value due to lack of exact data. Potential values are:rare, sporadic, frequent.
External influences on habitats
Degree of habitat loss – Deterioration caused by roads was assessed. Potential values are:small, medium, high.
Degree of fragmentation – The extent of fragmentation caused by the present road system. Po-tential values are: small, medium, high.
Success of invaders along corridors – An estimation based on field experience of the chanceof alien invader species to move along roads leading across a given habitat and to enter thestands of the habitats. Potential values are: little, medium, great.
Role of corridors in the secondary formation of habitats – The ability of a habitat to appearsecondarily along roads. Potential values are: small, medium, great.
Potential of pollution – The extent of pollution intrusion into the habitats. Potential values are:little, medium, great.
Possibility of hydrological change – The influence of roads on the hydrological condition ofthe affected stands. Potential values are: little, medium, great.
Enhancement of erosion – The influence of roads on erosion. Potential values are: little, me-dium, great.
Synthesized index of habitat susceptibility
Susceptibility of habitats to fragmentation – A combined measure of the above features. Po-tential values are: little, medium, high. It is worth noting that little or high susceptibility can bethe result of several combinations and therefore, it does not substitute for the above database.
Effects of the road network on animals
Arthropods
Arthropods of different life cycles are susceptible to the influence of traffic to various extents(Mader et al. 1990). Traffic can cause considerable damage to insect populations that fly in ashort period of time in great numbers over roads. Such are, primarily during swarm, some bees(e.g.: Apis mellifera), some beetles: the protected stag beetle Lucanus cervus or aquatic bee-tles: the protected great black water beetle Hydrous piceus, or members of the water beetle(Dytiscidae) family. Several nocturnal and diurnal butterflies are also threatened. Diurnal spe-cies are much more endangered by traffic than nocturnal ones (water scavenger beetles, waterbeetles, aquatic bugs). As opposed to swarming behaviour (limited only to a short period of theyear), arthropods whose feeding and dwelling habitats are divided by roads, are restricted orravaged by traffic during nearly the whole vegetation period. Similarly, aquatic beetles are
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Chapter 4
also in danger, owing to nocturnal dispersion swarm characteristics. As they cannot differenti-ate between water surface and the similarly glittering wet road surface, they might land on theroads and fly away with difficulty. This way enormous numbers can be killed by traffic.
Carnivorous or necrophagous protected carabids may also fall victim to road traffic, as theyfeed on the carcass of previously run-over animals lying on roads (Eversham & Telfer 1994).Distinction must be made between good flyers (hymenopterans, dragonflies) and poor, slow,straight flyers (beetles, butterflies), the latter group being much more vulnerable. Beside thedirect impacts, bare road surfaces stretching long distances can cause the fragmentation ofpopulations too. Studies have shown that road-like objects deter some insect species [lady-birds (Coccinellidae) (Sárospataki & Markó1995), hover-flies (Syrphidae) (Lõvei et al.
1998)] from trying to fly over. This phenomenon is caused by the ecophysiological propertiesof roads completely different from the habit and microclimate of the surrounding environ-ment. As a result, gene-flow among the subpopulations becomes highly restricted or evenceased, which may cause their genetic impoverishment and finally extinction. The majority ofwild bee species use various habitat fragments (hive habitat, feeding habitat, nesting materialcollecting habitat), which, if separated by roads can cause the decline of the given Hy-menoptera population (Matheson 1996).
Amphibians
The group of animals belonging to the most threatened organisms as regards both abundanceand species number is the class of amphibians (Bakó 1999; Hels 1999). Several works provethat road traffic drastically decreases the abundance of amphibian populations (Puky et al.1990; Hels 1990). The reason is that most amphibians have different habitats for mating,overwintering and feeding (Marián 1987). Fire salamanders, newts and frogs, waking up fromhibernation in spring start migrating to small or large ponds to mate and lay their eggs. Should
Figure 4.2.1. Slow-moving migrating species like the common toad (Bufo bufo) are especiallyendangered.
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this migration route be crossed by a road, as much as 70–90% of the population may be de-stroyed under car wheels. The influence of roads on amphibians is species specific. The num-ber of perishing individuals basically depends on the daily activity and migration speed of thegiven species compared to the density of vehicles and the width of road surface (Hels 1999).The daily distribution of traffic is equally important. At roads where traffic is evenly distrib-uted in time, the daily activity pattern is less important. Such roads are motorways and otherheavy traffic roads (e.g.: highways leading to the frontier). The migration speed of species hasa more prominent role in the survival of a given individual in these cases, than does the inten-sity of traffic (Hels 1999). Another complicating factor is that the majority of frog species [e.g.toads (Bufonidae)] were found to behave in a different way on road surfaces, than on naturalground in the herb layer. Roads, having a higher temperature than the surroundings, coupledwith better sight conditions, make frogs pause and linger on the roads for long (Puky et al.
1990). Being cold-blooded animals, frogs are very keen on staying on the warm surface ofroads and furthermore males are more likely to catch sight of females approaching ponds. At acertain level of traffic intensity the number of adult amphibians drops so drastically, that thenumber of eggs laid will be lower than if eaten by predators. Consequently – although somespecimens manage to survive the slaughter of traffic and even reproduce – the survival of thepopulation becomes uncertain (Hels 1999).
Not all amphibian species are threatened equally in Hungary. Vulnerability depends on the mi-gration features, avoiding strategy, and population size of the species. Slow-moving animalsthat migrate in concentrated, large masses are most prone to danger. Such species are the com-mon and green toad (Bufo bufo, Bufo viridis), the spadefoot toad (Pelobates fuscus), to a lesserextent the fire salamander (Salamandra salamandra), the crested newt (Triturus cristatus),the European treefrog (Hyla arborea), the agile frog (Rana dalmatina) and the common frog(Rana temporaria) living in the Northern Mountain Range. Amphibian larvae become smallfrogs in July and August and leave the water to migrate to their feeding and overwintering hab-itats. Although this migration is less intense than in spring, the number of animals can be manytimes more than that of adults migrating in the mating season.
Reptiles
Traffic has been found to be less dangerous for reptiles than for amphibians. One reason is thatreptiles do not migrate in masses and besides, their populations are usually smaller (Bakó1999; Marián 1987). Another reason is that most reptiles – principally lizards – have a moreeffective avoiding strategy. Still, a lot of tortoises [European pond turtle (Emys orbicularis) inHungary] and lizards (Sauria) fall victim to traffic.
The explanation lies in the fact that Hungarian reptiles are all diurnal, so high intensity dailytraffic can cause considerable damage to their populations. The European pond turtle is out-standingly endangered, as it lives in freshwater but lays its eggs far from the water in sand orloess. The distance covered can be the order of a kilometre. Beside being slow moving, the Eu-ropean pond turtle is vulnerable also because of its poor defensive strategy (the animals retreatinto their shell in case of danger). The young hatching from the eggs at the end of summer startmigrating to the water nearly at the same time in great numbers. Traffic can cause considerabledamages to a population in this case. Altogether there are two highly dangerous periods in thevegetative season of turtles. For similar reasons, but to a lesser extent, some snake species are
28
also threatened: the Aesculapian snake (Elaphe longissima), the smooth snake (Coronella
austriaca), the water dwelling dice snake (Natrix tessellata) and the grass snake (Natrix
natrix).
Reptiles – primarily lizards and snakes – often creep to road verges or even onto the asphalt inorder to warm themselves on the road surface which is hotter than the surrounding areas.These shrubby roadsides are often the most popular territories for some lizards [green lizard(Lacerta viridis), sand lizard (Lacerta agilis)] (Korsós 1982). Large amount of lizards fall vic-tim to the drifting force of fast vehicles.
The greatest threat for reptiles, just like for other animal taxa, is the habitat segregation effectof roads especially for endangered species with small population sizes. A good example is asubspecies of the Danubian meadow adder (Vipera ursinii rakosiensis) living exclusively inHungary, in the Hanság and Kiskunság regions, or the sand lizard Podarcis taurica in the Dan-ube–Tisza interfluve. As a result of road construction the water supply of the nearby fens isalso at risk. Since the common lizard (Lacerta vivipara) – a relict species of Hungary – isstrictly confined to such habitats in the Kiskunság region, the fragmentation of fens results in adrop in their populations.
Birds
The endangering effects of traffic on birds (Aves) are principally direct, caused mainly by run-ning over. Certain bird species are attracted by roads and get more often knocked down bycars. Seed-eating or granivorous birds [green finch (Carduelis chloris), goldfinch (Carduelis
carduelis), hawfinch (Coccothraustes coccothraustes), etc.] may feed on grains fallen fromcereal transporting lorries. Insectivorous shrikes [red-backed shrike (Lanius collurio), greatgrey shrike (Lanius excubitor), lesser grey shrike (Lanius minor), swallows and martins(Hirundinidae)] and small predators that chase small birds alerted by traffic [sparrow hawk(Accipiter nisus), kestrel (Falco tinnunculus), hobby (Falco subbuteo), etc.] often choosefences and other erect objects along roads as their watching places. In the eastern part of thecountry red-footed falcons (Falco vespertinus) are often seen sitting on posts along roads asthey look for orthopterans over the roads. Buzzards (Buteo buteo) are also frequently found inwinter sitting on the tip of lamp posts, watching small mammals. Although the above speciesare very good flyers, they frequently get run over by the modern fast and silent vehicles. How-ever, more birds die by electric shocking during landing, sitting or flying through electric in-frastructures (poles and wires).
After road constructions borrow pits filled with water are often left behind, which usually in-crease biodiversity. However, water birds (ducks, grebes, waders) are at risk due to the prox-imity of roads.
Heavy traffic roads might cross the flight route of bird species that nest in the wayside shrubbyvegetation [tits (Paridae), pigeons (Columbidae)]. In such cases even flocks of birds may beknocked down.
Species that nest on the ground and fly low and slowly (partridges, pheasants) are also endan-gered by traffic (Lachlan 1976).
The probability of road kills greatly depends on the speed of vehicles. Birds have generallybeen observed to be incapable of avoiding cars travelling faster than 70–80 km/h. Thus, each
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type or section of road that carries cars running at a speed higher than this means a potentialthreat to birds.
Mammals
When discussing the effects of roads on mammals, distinction should be made between smallmammals and larger game. The first group is less visible and has a poor avoiding strategy,while the latter has a more complex avoiding strategy and may even be potentially dangerousfor passengers. Among small mammals, principally those feeding on animals or plants nearroads are endangered by the direct effects of roads. The nocturnal Eastern hedgehog (Eri-
naceus concolor), some shrew species (Sorex araneus, S. minutus, Clethrionomys glareolus)or the common hamster (Cricetus cricetus) protected in Europe but pursued in Hungary, mayall feed on the carcass of run-over animals. Hamsters, however, mainly collect grains fallen onthe road surfaces, as do voles (Microtidae) and mice (Muridae).
The habitat fragmentation effect of roads primarily affects animals that avoid bare surfaces.Such mammals are the Hungarian dormouse species (Myoxidae) (Bakó 1996; Bakó et al.1998; Morris 1997) and the water shrews [northern water shrew (Neomys fodiens), southernwater shrew (Neomys anomalus)].
Bats (Chiroptera) can also frequently get run over at dusk by vehicles of high speed.Wire-fences generally used in Hungary are not suitable for the protection of small mammalseither, as the animals easily climb through or over them. Frog-tunnels, however, are more fre-quently used by mice and voles than by frogs. Driving fences, on the other hand, are too lowand do not hinder these mammals from climbing or jumping over onto the road surface.
Considering game run-over, roads leading through habitats permanently or temporally usedby large populations are especially crucial. Such permanent habitats are extensive, contiguouswoodlands (Mátrai 1996) and natural grasslands. Agricultural fields (maize, rape, cereals,etc.) may serve as temporal habitats for great numbers of game.
4.3. OVERVIEW OF FRAGMENTATION DUE TO DIFFERENT LAND-USES
State of nature, species and landscape diversity are basically affected by the land-use structureof the country, by the ratio of cultivated/abandoned land and by the extent of nature-friendlyland-use practice within the cultivated areas. Figure 4.3.1. demonstrates the present situationin Hungary.
Changes in land-use accelerated after the middle of the twentieth century and – as a conse-quence – we can witness several, usually undesirable processes in the state of the landscapesof the country. Structure of the landscape had been altered as field sizes were increased forlarge-scale agriculture, while the formerly scattered, mosaic-like feature of landscape wastransformed and the diversity decreased at the same time. Parallel with these processes thenumber of characteristic elements, unique landscape values were decreased. However, theradical changes in the conditions and practices of agriculture as a result of the political changesin the early ‘90s affected and are permanently affecting landscapes in a different way. Accord-ing to the productivity fo soils and the new requirements of owners the major part of the for-merly large-scale agricultural system becomes mosaic-like again. Area of uncultivated as wellas of temporarily or permanently abandoned land is increased.
Among factors threatening or degrading landscapes of the country the following need to bestressed:
• ill-considered investments (agricultural and industrial plants, linear infrastructure) whichwere established without respecting the standpoints of landscape harmony in severalplaces,
• the homogenising effect of large-scale agriculture and forestry, like the elimination oflandscape elements (rows of trees, hedgerows, forest belts) that have previously increasedthe variability of landscape by ensuring diverse habitats,
• the expansion of built-up areas that is one of the unfavourable side-effects of infrastructuredevelopment.
The simplified impact matrix (Table 4.3.1.) helps to compare the effects of the different linearestablishments on the land-use potential and on the habitat and landscape diversity of Hun-gary.
Effects of fragmentation are different in different areas, for example in built-up and urbanisedregions, in intensively cultivated agricultural lands or in quasi-natural habitats, forests orgrasslands.
Fragmentation and urbanisation
Increasing the density of linear infrastructural networks in urbanised areas is a great pressureand an aspiration (required and wanted) at the same time. This contrasting interest manifestsduring the development of the road network: after reaching a certain level, the fragmentationeffect of linear infrastructures becomes the drawback of further development by restrainingthe realisation of ecological and landscape requirements. Linear establishments support ur-
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Table 4.3.1. Environmental impacts of linear infrastructures
roads railway conduitProductpipeline
Electric transmissionnetwork
Irreversible habitat destruction +++ + ++ + +
Reversible habitat destruction ++ + + + +
Habitat fragmentation +++ ++ ++ + ++
Altering amenity value of landscape ++ + + + +++
Transforming surface features ++ + + – –
Altering soil conditions ++ + ++ + –
Changing microclimate ++ + + + –
Modifying hydrological conditions ++ + +++ – –
Polluting environment +++ + + – –
Accidents and damages + + ++ +++ –
Sum of + 22 11 16 9 7
Key to classification: the effect is very significant = +++; significant = ++; moderate = +; insignificant = –.
banisation at the beginning, while interfere with newer needs of inhabitants for more naturalareas in built-up regions later.
Fragmentation and agriculture
Considering different aspects of fragmentation on agricultural production will lead to differ-ent judgements. On the one hand the linear structures break up agricultural lands and decreasefield sizes, increase habitat diversity, the ratio of margin- and micro-habitats that all are veryimportant (feeding, reproducing, overwintering, resting or corridor) habitats of many smaller-sized animal species. These areas also have outstanding importance from the point of view ofbird protection (see partridge and great bustard survival projects, Faragó 1997). On the otherhand the increasing length of accessing routes, closing crossovers, forcing power machines toroundabouts or longer passages belong to the disadvantageous effects of infrastructure. Thereare also indirect damages, among them the increase of environmental threats, the proliferationor pullulation of pests, the damage of nature, the pollution of agricultural products and others.
A great change in land-use, was initiated by the construction of the M7 Motorway that is con-necting the capital and the greatest recreation area, the Lake Balaton. The opening of the mainroad increased the built-up ratio not only in the Balaton region but everywhere along the roadfrom the Tétény Plateau through the margins of the Velence Mountains to the Lake. Great ara-ble lands, extended vineyards and fruit gardens were abandoned and especially at the close vi-cinity of the motorway chaotic-like recreation plots and areas were evolved.
The railway line established first at the southern and later at the northern side of the LakeBalaton modified the land-use relations of the region. Viniculture and fruit production, reedmanagement and fishery formerly all traditional to the region were entirely pushed into thebackground by tourism. Sight of the landscape has basically been changed. Built-up ratio hasbeen multiplied and the natural shore line of the lake simply disappeared in most places. Tradi-tional farming decreases at the same time the area becomes more and more overcrowded pre-venting recreation itself.
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Figure 4.3.1. Break down of land-use classes in Hungary (Institute of Geodesy, Cartographyand Remote Sensing, 1999)
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Chapter 4
Fragmentation and semi-natural habitats
As it was shown in the above table every linear infrastructure induces undesirable changes insemi-natural habitats. Distinction has to be made, however, within the different infrastructuralelements depending on their size, capacity and realization. Fragmentation effect of earthtracks, footpaths, unpaved forestry tracks, narrow-gauge railway line is little and these linearstructures do not cause basic changes in land-use. Covered roads and standard railway lines in-crease the accessibility of areas for the human population and in suitable conditions transformthe former extensive or abandoned land-use types radically.
The driving force in developing certain regions are the roads, primarily the motorways. Roadtracks remained constant for centuries – or even for millennia as the military roads of the Ro-man Empire in the Transdanubian region. Areas connected by public roads or nowadays byexpressways were and are upgraded. Differentiation between regions or settlements by the ex-istence or the lack of motorway connection has become common. The motorway increases thebuilding and investment activity as well as further strengthens the transformation of landscapeconditions. As a summary one can state, that with planning more intensive traffic, a higherspeed and a shorter arrival time, motorways and railways become less adjusted to the land-scape features and their fragmentation effect is the greatest.
In extended, closed forests the establishment of standard-gauge lines resulted in the develop-ment of marginal habitats with different species composition and lower biodiversity and in thealteration of water regime and microclimate. A good example for this process is the environ-ment transformation made by a natural gas pipe established through the floodplain of theTisza. There a hardwood alluvial forest – an association disappearing from Hungary – wasopened in a wide tract for the pipe. The opening of the alluvial forest altered the microclimateof the southern part and consequently the relict endemism snail species, the Helicygona
banatica ssp. hungarica became extinct from the area.
The greatest impact on the grasslands and forests of Hungary were the big water regulationprojects, the channel constructions in the past two centuries. Areas in the size of a region(Hanság, Great Hungarian Plain, Sárrét) lost the variability and diversity of their plant and ani-mal life by “defeating nature” for the sake of gaining new croplands. Decades later the unex-pected consequence was discovered: the majority of areas conquered from nature were notsuitable for large-scale agriculture/crop production.
4.4. ADMINISTRATIVE AND LEGISLATIVE FRAMEWORK
4.4.1. Environment and nature protection
The 53/96 Act of Nature Conservation gives the framework of preserving natural values andnatural areas, landscapes together with their natural systems and biodiversity. Beside the gen-eral regulations, the specific regulations of the 7th paragraph dealing with landscape protec-tion give the rules of establishing linear infrastructure as follows:
7. § (2) For the purpose of preserving landscape character, natural values, unique landscapevalues and aesthetical features:
(a) the harmonisation of linear infrastructural establishments and appliances (installations) tothe landscape has to be ensured during construction by functionally and aesthetically reconcil-ing natural values and artificial environment;
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(g) motorways and other linear establishments crossing known movement corridors of wild-life need to be constructed in such a way that allows in suitable intervals the individuals ofwildlife species to cross it;
(h) subsistence of characteristic landscape elements needs to be assured.
The Law of Nature Conservation effective at present allows stronger protection to non pro-tected areas than the earlier legal measures by defining the concept of natural areas (forest,grassland, reeds, areas withdrawn from cultivation, as well as lands not suitable for farming orforestry) in paragraph 15. and by restricting the activities in these areas, among them the linearinvestments.
Similarly to the earlier regulation, the nature conservation authority is the legal authority in thelicensing procedures of establishing linear infrastructures on/through protected areas (para-graph 39. of the Law). With the exception of nature protection management, all activities,among them the establishment of linear infrastructures are forbidden on strictly protected ar-eas.
The structure and organisation of the national body of nature conservation are prescribed inparagraphs 56–58: the Minister of Environment supervises the nature conservation activities.Administration tasks of nature conservation belong to the National Authority for Nature Con-servation supervised by the Minister at the second instance and at first instance to the nationalpark directorates or to local governments (in case of areas or values protected at local level).There are nine national parks in Hungary at present. Areas belonging to the different nationalpark directorates and their basic data (registered also in the nature conservation inventory) areshown in Table 4.4.1.1. and in Figure 4.2.4.2.
The 53/95 Act of Environmental Protection orders that before starting any activity signifi-cantly affecting the environment, an environmental impact assessment has to be prepared(paragraph 67). Activities falling under the scope of this regulation as well as the detailed ad-ministration procedures are prescribed in Government Decree number 152/1995. (12. Dec.)which lists among others the following linear establishments that need preliminary impact as-sessment:
• public railway,
• motorway, expressway,
• primary road,
• secondary road if driven across forest greater than 50 hectares,
• underground railway,
• oil pipeline, natural gas pipeline, oil-product pipeline,
• main irrigation canal if not covered,
and moreover in protected natural areas of national or local importance:
• aerial cable,
• road for permanent use,
• railway for agricultural and forestry purposes,
• underground/subsurface conduits.
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Chapter 4
Status of nature conservation in Hungary
One of the principal aims and tasks of nature conservation is the establishment of the networkof protected areas. Since the designation of the first protected areas – more than a half century
Table 4.4.1.1 Most important data of national parks
No.Registrationnumber
National parkExtension of protectedarea (ha)
Nature conservation manager
1 177/NP/85 Aggtelek NP 19892.0 Aggtelek NP Directorate
2 282/NP/97 Upper-Balaton NP 56997.8 Upper-Balaton NP Directorate
3 138/NP/76 Bükk NP 43129.8 Bükk NP Directorate
4 271/NP/96 Danube-Dráva NP 49473.0 Danube-Dráva NP Directorate
5 283/NP/97 Danube-Ipoly NP 60314.1 Danube-Ipoly NP Directorate
6 238/NP/91 Fertõ-Hanság NP 23588.2 Fertõ-Hanság NP Directorate
7 97/NP/73 Hortobágy NP 80548.9 Hortobágy NP Directorate
8 109/NP/74 Kiskunság NP 56761.0 Kiskunság NP Directorate
9 276/NP/97 Körös-Maros NP 50134.0 Körös-Maros NP Directorate
Source: National Authority for Nature Conservation, Ministry for Environment
Figure 4.2.4.1. Extension of protected areas of national importance between 1939 and 1999
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ago – important steps have been made forward in the field of nature conservation. In 1939 thegovernment designated 273 hectares for protection within the present territory of Hungary.That area increased to 630.124 hectares till 1990 and to 849.749 hectares till January 2000,representing 9.1% of the territory of Hungary (see Figure 4.2.4.1). 11–12% of the country areais the target for protection by legal means in the long-term.
Table 4.2.4.1. Trends in number of protected species
of different taxonomical groups between 1990 and 2000
Numberof knownspecies ofthe world
Speciesnumberin Hun-
gary
Protected Strictly protected Altogether
1990 1994 2000 1990 1994 2000 1990 1994 2000
PLANTS 350000 3000 415 454 464 31 47 52 446 501 516
Mosses 25000 589 19 20 20 0 0 0 19 20 20
Pteridophyte 13000 60 27 38 38 0 1 1 27 39 39
Gymnosperms 640 8 0 1 1 0 1 1 0 2 2
Angiosperms 311360 2343 369 395 405 31 45 50 400 440 455
ANIMALS 1250000 42016 573 781 771 46 76 84 619 857 855
Invertebrates 1205000 41460 180 398 389 0 0 0 180 398 389
Vertebrates 45000 556 393 383 382 46 76 84 439 459 466
Cyclostomata * * 0 0 2 0 0 0 0 0 2
Fishes 22900 81 26 28 25 0 0 1 26 28 26
Amphibians 3000 16 16 16 16 0 0 0 16 16 16
Reptiles 6300 15 13 13 13 2 2 2 15 15 15
Birds 8700 361 289 275 278 38 65 70 327 340 348
Mammals 4100 83 49 49 48 6 9 11 55 58 59
ALTOGETHER 1600000 45016 988 1235 1235 46 123 136 1065 1358 1371
* no data
The greatest part of designated land is protected at a national level and the nine national parksthemselves represent 440.839 hectares among them. There are 38 protected landscapes withan extension of 349.242 hectares altogether, 109.577 hectares of which are under strict protec-tion. The most rigorous management and visit regulations operate at strictly protected areas.1067 sites are protected at local level and their extent is altogether 35.800 hectares. The mostimportant nationally protected areas are shown in Figure 4.2.4.2.
It is worth mentioning here, that since the middle of the seventies a continuous and gradualconsolidation of nature conservation could be witnessed in Hungary. Since that time the desig-nation of protected areas has been accelerated (see Figure 4.2.4.1). The first national park wasfounded in 1973, three others were established and the foundation of the fourth was preparedtill 1990. This progress successfully continued after the political changes and the extension ofprotected areas approaches 850.000 hectares in 2000. Meanwhile the countrywide network
of 9 national parks was established (and is working with the guidance and supervision of thenine national park directorates).
Protected natural values without protected location
The protected natural values without defined area are the protected plant and animal species,natural monuments, unique landscapes and protected values like fens, caves, etc. The presentstudy deals only with protected species from the above listed entities.
The first species were protected at a national level in 1982 in Hungary. The first protected spe-cies lists aspired to reach a “minimum list”, protecting the most important plant and animalspecies at least. During the past almost twenty years the lists were more times amplified and in1996 they were considered to be scientifically correct and complete concerning higher plantspecies and animals. Lists need periodical revision for including new scientific results. Evenin medium time scale the status of a given species may change so much – owing usually to theachievements of nature conservation – that the status of the species is worth changing in thelegislation. Other plant or animal species can become scarce or even frequent on the opposite.For example the formerly very rare cormorant (Phalacrocorax carbo) became frequent in Eu-rope thus was deleted from the protection list. However, the circle of protected species is nottotally covered yet in Hungary because nature conservationists try to compile for example thelist for mosses, lichens and fungi’s lists at present. There are proposals for protecting plant as-sociations and a detailed decsription of plant communities with proposals for protection initi-ated by the National Authority for Nature Conservation was published in two volumes in 1999(Borhidi & Sánta 1999).
Plants
About 2400 higher plant species (together with the so-called microspecies) are living in Hun-gary (see Table 4.2.4.1.). The lack of precise numbers results from continuous debates aboutspecies/subspecies identification and of course from the most recent taxonomic researches.Sixty species belong to pteridophytes (2.0%), 8 are gymnospermous (0.26%) and 2343 are an-giospermous (78.1%). 516 species of the flora of Hungary is protected at present, 52 of whichis strictly protected. This means a respectable part, 17.2% of the flora. Among lower plant spe-cies, 20 Sphagnum species are also protected. Protected as well as several yet not protectedrare species of high natural value are actually or potentially endangered with some exceptions.These species/populations can be preserved exclusively by the maintenance of their habitats.This is true even if many examples prove that they can be reproduced in horticultural/botanicalgardens. The importance of “cultivated” stocks is their potential in strengthening and increas-ing the original (endangered) populations at the original habitats.
Animals
Among the 81 fish (Pisces) species of Hungary 26 are protected and the only strictly protectedspecies is Danube trout (Hucho hucho). All the 16 species of amphibians are protected there isno strictly protected amphibian in Hungary. Similarly all 15 species of reptiles of Hungary areprotected, two of which, the green whip snake or racer (Coluber jugularis) and the meadow vi-per (Vipera ursini rakosiensis) are strictly protected. 348 of the 361 birds of Hungary are pro-tected and 70 of them are strictly protected. 59 of the 83 mammal species are protected and 11of them are strictly protected. Altogether 389 invertebrate species are protected in Hungary atpresent.
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Habitat protection
Single species – plants or animals – can not be preserved successfully. Only species togetherwith their habitats are possible to protect. Physical and biological elements of habitats serve asimportant environmental factors for species (e.g. the different plant associations and the dif-ferent physical surface elements are the scenes/subjects of breeding, feeding, wintering, rest-ing activities of animals). Communities of living organisms are mainly determined by theirplant associations (fundamental units of the flora).
Today 470 plant associations are registered by botanists within Hungary. 350 of them can beconsidered natural and semi-natural associations and about 120 are of antropogenous origin114 of which are markedly weedy associations. Not less than 218 associations, 62% of naturaland semi-natural associations require basic or higher level protection (Borhidi & Sánta 1999).
National Ecological Network
The elaboration of the National Nature Protection Strategy as part of the National Environ-ment Protection Strategic Plan was ordained in the Paragraph 53. of the Law of Nature Con-servation (53/1996). The aspects of establishment and maintenance of a National EcologicalNetwork are included in the above mentioned strategy. The National Nature Protection Strat-egy was submitted to the Parliament and passed in 1997. Afterwards – with the overall co-or-dination of the National Authority for Nature Conservation of the Ministry for Environment –the National Park Directorates elaborated the plan of the National Ecological Network in thescale of 1:500.000 (see Figure 4.2.4.3.), in accordance with the regional regulation principlesof the Regional Policy Plan of Hungary.
During the elaboration of the National Ecological Network – beside following the Hungarianregulations – the following international agreements of outstanding importance (and theirdeadlines) had to be considered:
Pan European Biological and Landscape Diversity Strategy. All signatory countries of theStrategy have to designate core areas, ecological corridors and nature development areas(buffer zones) within their national ecological network (as the directives of the competentcommittee of the Council of Europe, April 1999 orders).
The areas belonging to the EU “Natura 2000” ecological network, such as the “Special Protec-tion Areas – SPA” (regulated by the bird protecting directive no. 79/409 of the EEC), as wellas the “Special Areas of Conservation – SAC” (ordered by the EEC directive no. 92/43 forhabitat protection), and the habitats of threatened species or species requiring special protec-tion of the EU all are parts of the National Ecological Network.
The national park directorates have recently finished the compiling the map series (scale1:50.000) of the regional ecological networks. The international outstanding significance ofthe regional ecological map series lies in the fact that it intends to meet requirements and to useelements of the above mentioned two systems.
40
COST 341
Con
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4.4.2. Administrative and legislative framework for traffic and transport
Surface roads
The Law of Traffic on Public Roads (1. of 1988) deals with developing public traffic (para-graphs 10. and 11.). The law laid down the principles that “road development plans and re-gional/local development policies should be coherent. Roads need to be developed in the waythat public roads (national and local public roads) and open private roads form a continuoussystem.” During developing the road network the traffic and transport requirements should bethe prime factor, and among others, the interests of environment and landscape protectionhave to be considered as well.
This law orders that “an independent, special policy plan of developing the national networkof roads has to be elaborated, and submitted for approval to the Government by the Minister ofTransport, Communications and Water Management”.
The following framework plans were elaborated for developing the public road system:
• National road development plan, which deals with the development concept of primary,secondary roads and national road network.
• National motorway-expressway network development scheme – for motorways and high-ways.
• Roads maintained by local municipalities – only Budapest finished the plan of “Transportsystem development plan of Budapest”. In the case of the other settlements the localregional planning policy includes the network development concepts.
Based on the listed framework, the road network managers are the decision makers in develop-ments, they initiate planning projects. The designing engineers complete the plans accordingto the technical regulations. Among them the most important is the transport sectoral standardtitled “Designing public roads” (ME-07–3713:1994).
Authorisation process for public roads
For roads included in policy plans a study (draft) plan is elaborated. The environmental protec-tion plan is a compulsory part of the study plan. Depending on road type and areas affected apreliminary impact assessment has to be made parallel with the study plan. The route (layout)options of the impact assessment will be evaluated by – among others – the environment pro-tection authority during the process of licensing. The layout for detailed road planning will beselected on the base of the opinions of competent authorities. The Road Management andCo-ordination Directorate approves the chosen trace in the case of important networking roads(national roads).
After first approval the detailed licence plan has to be submitted for confirmation to the roadmanagement authorities. The first instance administrative authority is the competent countytraffic authority in the case of national roads and roads out of the capital and the Central TrafficAuthority in case of highways. The environment protection agencies are the special assentingauthorities for the environment protection chapter of the license plan, they issue the environ-ment protection license for the detailed impact study, and they co-ordinate the work of othercompetent authorities on the impact assessment. The approval of all competent authorities isthe minimum requirement for issuing the construction plan.
41
Chapter 4
Railway
As the referring law (95. of 1993) defines, railway is a fixed track transportation system for
transporting passengers and goods. Constituents of the system are the fittings of the railroad,
the operating equipment and units, the railway vehicles and the working administration oper-
ating all above and implementing passenger and goods transport.
The law states that development of railroad transport is a state duty. The National Railway
Statutes enacted by the No. 28/1994 (28. Oct.) Decree of the Ministry of Transport, Communi-
cations and Water Management order that railway development policy plans have to be made
for the national railway network and to the main lines.
The line planning is based on the National Public Railroad Planning Rules, which lists the im-
portant aspects to be considered during planning public railroads, among them the long-term
demands on development. Using land for railroad development purposes is allowed only in
agreement with the regional plans, consequently railroad and other sectoral provisions of the
regional plans have to be considered during planning.
Waterways
The Law of Water Resource Management (57. of 1995) contains the general rules and duties
regarding waters and waterworks. The regulations of the Law cover primarily the water uses
of water management and the conditions of them – in accordance with the Law of Environ-
ment Protection. Among activities affecting surface waters the mostly emphasised ones are
flood prevention and inland drainage together with governmental and local governmental
tasks regarding these. The Law does not treat water transport and related interventions.
4.5. LAND-USE PLANNING IN RELATION TO NATURE AND LANDSCAPE CONSERVATION
AND TRANSPORT
The 21/96 Act on Regional Development and Physical Planning defines the country and re-
gional development and planning duties and aims. According to the law the transport unit and
the nature conservation unit are inherent parts of the regional policy plans. Regional develop-
ment and planning purposes are prescribed in paragraphs 2/b. and 2/c. as follows:
Paragraph 2. aims of regional development and physical planning are:
• (b) “for the sake of ensuring the equal social chances: to moderate the significant
differences in living conditions, economy, culture and infrastructural conditions between
the capital and the country, the towns and the villages, or the developed and the backward
regions and settlements; to prevent the evolution of new crisis areas,”
• (c) “to promote the harmonic development of the spatial structure and settlement system of
the country”.
Paragraph 23. defines the bases of regional planning: they are the regional development pol-
icy, the regional development programme and the physical plan. The physical plan – in accor-
dance with the aims defined in the regional development policies – lays down the land-use
method of the area regarded. It contains moreover:
• the spatial organisation of the regional technical/infrastructural systems,
• the long-term regional system of the area regarded,
• the appropriate use of the conditions of the given areas,
• the regional tasks concerning environment, landscape and nature conservation.
42
COST 341
43
Chapter 4
By paragraph 5. the regional development policy is a scheme that lays the foundation of and isthe determinant factor of the overall and long-term development of the country or a region,which specify the long-term and general development purposes as well as the guidelines nec-essary for elaborating the development programmes and which support the participants of thesectoral planning and the related regional planning and development with information.”
The No. 18/1998. (25. June) Decree of the Ministry for Environment and Regional Policydeals with the content requirements of the regional development policies, programmes and re-gional plans.
Content requirements of the regional development policies are defined in two phases namely itprescribes a preparatory and a proposing phase. The preparatory phase has three main parts:
• exteriors (external environment) of the regional unit,
• regional conditions (human resources, bases of economy, environmental factors, infra-structure, settlement network, social environment),
• possible directions of development.
Questions regarding infrastructure, its present status and possible developments have to beconsidered in both the preparatory and the proposing phase.
Settlement structure plans and physical plans are elaborated for the given settlement or settle-ment district. Physical plans and regional development policies are evaluated by different au-thorities (nature conservation, environment protection, transport and others), by publichearings and NGOs in certain cases. Physical plans and regional development policies serveas the base of following planning processes. In the case of planning a transport infrastructuredivergent from the physical plan, the regional plan has to be modified.
The No. 35/1998 (20. March) Parliament Decree about the Regional Development Policy ofHungary defines the prospect of regional development policy.
The main features of the policy are:
• belonging to the community of the European states, Hungary serves as connecting corridorin east-west and north-south directions – in accordance with its cultural heritage,geographical features, and developed national economy,
• the regions of different social and economical conditions are developing in differentindividual ways with intensive co-operation and in harmony but not in dominant/sub-ordinant relations with each other,
• the regional inequalities are being moderated, the number of disadvantageous regions withless developed social and economical conditions and with high unemployment ratio arebeing declined,
• the urbanisation axes and traffic corridors are integral parts of the European spatialstructure and they are dynamic elements of regional development.
Important environmental priorities in the area of regional development are:
• one of the most important purpose of regional development is ensuring maintenance andimprovement of the environmental factors required for acceptable living qualitiesespecially in the regions with high environmental pollution level,
• for the purpose of preserving the optimum state of environment the effects of transportcorridors, financial and trade networks, multinational bodies, energy transferring net-works and transit on the unique ecosystems of the Carpathian Basin have to beregularly surveyed and evaluated,
• regional development has to be realised by preserving natural systems, natural values andbiodiversity,
• regional development plans should be shaped and realised in the way they utilise wiselyand harmonically the environment; the conditions of which are the enforcement ofprinciples of sustainable development as well as the long-range maintenance of theoptimal state of environmental factors considered to be of vital importance (air, water,arable land) while using/managing natural resources.
Important technical infrastructural priorities of regional development:
• construction of freeway network, modernisation of railway network, development ofwaterways of the Danube and the Tisza have to be accelerated for the purpose ofimproving the access of regions and better utilisation of the advantages of the countrycoming from its favourable geographical location,
• the development of airports suitable for regional development (partly in form of privateinvestments) should deserve greater importance,
• for the sake of decreasing the environment pollution the role of combined transport ofgoods, water-carriage and rail transportation have to be increased and logistic centres atthe regions of the internationally most important border stations have to be established,
• circle route (by-passing) programmes relieving settlements from high traffic load have tobe continued,
• quality and level of mass public transportation have to be improved in the future as well,
• in accordance with the traffic and transportation policy of the European Union thetransport infrastructures connected with the European traffic corridors crossing Hungary(No. 4., 5., 5/C., 7., 10/B.) have to be developed.
4.6. SUMMARY
Natural status of Hungary is really favourable comparing to several Western European coun-tries. Deriving from its biogeographical location the biodiversity is high from the outset on theone part, while the relative underdevelopment of infrastructure caused less damages in naturein the past years than in the well-developed Western European countries on the other. Thegrowing knowledge of ecology, the strengthening of conservational awareness and the legalregulations reflecting all above – at least theoretically – create the challenge of bypassing theextended nature destruction found regularly in other countries. For a better understanding thenatural regions of the country, their values, characteristic land-use types, habitats and theirsensibility as well as certain aspects of fragmentation effecting habitats were drafted in thischapter together with the status of administration and relating legal regulation.
44
COST 341
Chapter 5. Habitat fragmentation due to existing transportation
infrastructure
5.1. INTRODUCTION
By Western European measures there are only few special publications dealing exclusivelywith the environmental effects of the inland transportation network in Hungary and publica-tions with some demonstration regarding this topic can hardly be found. Possible reasons ofthis scarcity are:
• the past and partially the present lack (missing enacting clause of the act) of relating legalregulations,
• the lack of financial resources in every sectors, among them in the field of environmentalprotection,
• increase of environmental consciousness has developed only in the last 10–15 years,
• basic researches were and are in delay because of lack (legal, financial and ethical)support.
A comprehensive and countrywide study regarding habitat fragmentation effects of the roadnetwork was made within the frame of this COST 341 project by the Research Institute of SoilSciences and Agricultural Chemistry (RISSAC), at first in Hungary (results are shown in casestudy no. 3).
An investigation about the environmental damages caused by the inland railway transporta-tion was made in 1995. However, this study did not concern the effects on nature. Total rail-road length is 12.749 km (source: Hungarian Statistical Year-book, 1998), about an eighth ofthe road network. The only permanent fairway of Hungary is the Danube (inland length is415 km), while the Tisza (the Hungarian section is 595 km long) is partially navigable. Bothwaterways are natural water currents thus no habitat fragmentation effect is expected.
5.2. TRANSPORTATION NETWORK OF HUNGARY
The spatial structure of Hungary is dominated by a centralised transportation network with thecapital, Budapest in the centre (Figure 5.2.1.).
Common country level feature of both the road and the railroad transportation system is thelack of transversal connecting elements, namely the corridors (of suitable capacity) betweeneastern and western regions which – at the same time – would relieve Budapest and its Danubebridges. This feature results in the overburden of roads going to and from Budapest on one sideand in the lower than possible level of cooperation between the two parts of the country sepa-rated by the Danube. These difficulties in the transportation system originate from the TrianonDecree (1920), that resulted in the loss of peripherial connections.
5.2.1. Public roads
The road is a public or private domain serving the pedestrian and the vehicle traffic. The roadnetwork is the continuous system of national roads and roads of local governments.
Motorways connect countries or regions. These trunk-roads establish long-distance transportcorridors for the most intensively used routes of international and national importance. Theyprovide the highest service level and are made exclusively for the use of motor cars. They have
45
Chapter 5
46
COST 341
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at least 2×2 traffic lanes, a central reserve separating traffic to different directions and ahald-shoulder on the right side of the double lanes (except of special places). Motorways haveno crossing at grade in any type of intersection with transportation routes. A separated lane isto be made for the converging or the diverging (merging) traffic in the flyover junctions. It hasno exit to properties along the road.
Expressways interlink regions of the country. These roads are made for greater-distance traf-fic needs, have at least 2×2 traffic lanes, have no level crossing with railway. Their intersec-tion with other roads of intensive traffic is to be realised at split level. At grade junctionsexpressways usually have separate lane for left exit. For ensuring the movement of slow-mov-ing vehicles a parallel service road or other designated road should exist with separate gradecrosses in places where necessary. Expressways have no exit to properties along the road.
Primary roads interlink regions, important agglomerations or recreation areas which haveusually two lanes but may have more lanes in sections of high traffic. Newly planned or newlyreconstructed sections have no level crossing with railway. Junctions within sections of widerthan two lanes are grade separated. At grade junctions primary roads usually have separatelane for left exit. For ensuring the movement of slow-moving vehicles a parallel service roador other designated road should exist. They have no exit to properties along the road.
Secondary roads have distributor role within regions. They may have exit to properties alongthe road exceptionally.
Through roads are made for serving the through and greater local transport with their distrib-utor role within smaller regions (mesoregions).
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Table 5.3.1. Summary status of Hungarian road networks [km]
Settlement territory Outskirts Road network together
Character ofnetwork
Builtup
TotalBuiltup %
Builtup
TotalBuiltup %
Builtup
TotalBuiltup %
NATIONAL ROADS* 8398 8403 99.9 21514 21842 98.5 29912 30245 98.9
Main network 1486 1486 100.0 5501 5501 100.0 6987 6987 100.0
Secondary network 6912 6917 99.9 16013 16341 98.0 22925 23258 98.6
LOCAL ROADS** 32148 50545 63.6 3681 54688 6.6 35828 105233 34.0
Main network (1408) 2575 (529) 3306 (1937) 5881
Secondary network (21044) 47970 (1088) 51382 (22132) 99352
PUBLIC ROADS 40546 58947 68.8 25195 76530 32.8 65741 135478 48.5
Main network 4061 8807 12868
Secondary network 54886 67723 122610
PRIVATE ROADS 16206 52919 30.6 16206 52919 30.6
Private agriculturalroad
13670 48000 28.5 13670 48000 28.5
Private forestry road 2536 4919 51.6 2536 4919 51.6
* of Dec. 31.,1998.; ** of Dec. 31.,1995. (the 50/92 Act ordered to transform the ownership of cca. 25.000km long private roads to municipalities).
Side-roads are the roads not shown in the trunk road network of the country and all other roadsexcept of cycle tracks and pathways.
Forestry private road support mainly the forestry needs. Permanent forestry roads togetherwith their roadside ancillaries belong to forestry establishments. The general road traffic rulesare valid in the case of forestry roads as well with the amendments of the Law of Forests andForestry (no. 54/96).
5.2.2. Railway
The railway network of Hungary is of standard gauge (1435 mm). Typical gauge width of nar-row-gauge railway is 760 mm while forestry railways are of 600 mm gauge. Narrow-gaugerailways serve economical and recreational purposes.
Public railways may be classified by their network function and by transportation importance:
Category A.1. – international trunk lines
Category A.2. – national trunk lines
Category B.1. – other main lines
Category B.2. – side lines
Category C.1. – side lines with prohibited development
Category C.2. – side lines to be closed down.
Technical aspects of the planned line are determined on the base of the above classification.Important technical conditions are the followings: speed, axle load, free length of platformsand of tracks receiving arriving trains, permitted load, number of open tracks, type of pulling,system of saving means. Design speed for the different line classes is:
Category A.1. 160– 200 km/h
Category A.2. 120–160 km/h
Category B.1. 100–120 km/h
Category B.2. 60–80 km/h
5.2.3. Waterways
Inland waterway transportation is allowed on the following water bodies:
• natural water currents and lakes,
• regulated water currents and lakes,
• artificial channels.
Natural waters are navigable without any intervention. Regulated watercourses are thosewhich can be made navigable by water engineering and regulating means. A water current is tobe called canalised if the water depth necessary for shipping is ensured by barrage.
A waterway is artificial if a new bed is made for shipping purposes, i.e. in places with no orwith only insignificantly little water current. If the exclusive purpose of making an artificialwaterway is shipping, than this is a shipping canal. If it serves other interests as well (for exam-ple water transport, water supply) than this is a navigable canal. Waterways can be classified
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by their importance and tonnage of ships using them; we can distinguish waterways suitablefor small-scale shipping and regular shipping.
Ships with tonnage between 2.5 to 100 tonnes are allowed to use small waterways, while shipson regular waterways may have a tonnage of 250–3000 tonnes or more.
5.3. EFFECTS OF THE EXISTING TRANSPORTATION NETWORK ON NATURE
Only the effects of road network will be discussed in this chapter because no publication of ac-ceptable quality was found about the railway network effects on wildlife in Hungary. Data onthe present road network is demonstrated in the Table 5.3.2.
Table 5.3.2. Main data of the Hungarian public road network
(national and local network is distinguished on the basis of ownership).
National network Local network Total
Length (km) Land cover (m²) Length (km) Land cover (m²) Length (km) Land cover (m²)
30 244 193 493 105 233 173 693 135 477 362 656
Source: Road Database of the Ministry for Transportation, Telecommunications and Water Management, 1998
5.3.1. Habitat loss
One of the unfavourable results of fragmentation is the increasing edge-effect. Species andtheir ecosystems face with more severe environmental conditions at the edges of their habitat(considering their tolerance). Edge effect is greater if the proportion of edges to total habitatarea is greater. Among two-dimensional geometrical shapes the circle has the shortest propor-tional edge, and the most elongated rectangle has the longest. Explanation is the same for theadvantages of a greater patch contrary to a smaller one.
An investigation was carried out in this COST project to assess the risk of fragmentation ofhabitat types in relation to the present road network.
If we consider the average patch size of a habitat without and with the presence of a road whichindex reflects the fragmentation potential of the road, we can conclude that the extent of frag-mentation and the threatenedness of habitats to fragmentation are directly related.
GIS was applied to estimate the fragmentation effects of the Hungarian road network. The fol-lowing data sources were used:
• CORINE Land Cover database,
• Forestry maps (University of Sopron),
• Agro-topographical database (Environment and Landscape Management Institute, St.Stephen University),
• road network,
• habitat sensitivity estimations (see Table 4.2.1.).
The analysis was carried out for the following habitat sensitivity classes: low, medium, highsensibility types. With the help of GIS methodology, patch sizes of habitat classes have beencalculated with and without the road network. The shape of the patches was taken into consid-eration by comparing the area/contour ratio to geometrical shapes of the same area (circle,square, rectangle with size ratio 1:2 and 1:4).
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Chapter 5
Habitat fragmentation risk is demonstrated in Figure 5.3.1.1. Patch size for different habitatsensitivity classes changed differently with taking the road network into consideration: aver-age patch size became 71% of that of the situation with no roads for the low sensibility types,90% for the medium, and 91% for the high sensibility types.
These results demonstrate well the fact, that the most sensitive habitats are more or lessavoided by the road network (protected areas). The analysis of patch shape showed differencesin relation to sensitivity: the least sensitive habitats are elongated (the highest resemblance torectangle with side ratio 1:4), the habitats of the other two categories are mostly square shaped.The fragmentation risk of grasslands and forests differ: the sensitive grasslands and wetlandsare more threatened by roads than forests. This correlates well with the fact that valuable for-ests are situated in the mountain zone or alluvial area, where a dense road network is unlikelyto be placed. It can be stated, that the natural values of Hungary are moderately threatened bythe fragmentation effects of the present road network, conservation efforts have to be focusedon sensitive grasslands and wetlands.
5.3.2. Disturbance
The disturbing and damaging effect of operating roads and motorways can be manifold, theirdetailed summing up is beyond the scope of this study. A case study below represents the pos-sible disturbances of roads on the living environment.
Case study no. 1. BIOLOGICAL MONITORING ALONG THE M0 EXPRESSWAY,SECTION 0–14 KM – A SUMMARY REPORT
By A. Bankovics, O. Merkl, F. Németh and O. Pallag
The construction of the studied section of the M0 expressway, that should be provide aby-pass around Budapest for transit traffic was started in the second half of 1992. Theroad was opened in 1995. The aim of the investigations was to identify the damagescaused by the construction and operation of the studied highway section on the naturalvalues of the surrounding area.
Study areas
Sample sites of the observation system for nature protection were (are) situated in nat-ural or semi-natural habitat types along the studied route. One suitable site was themixed oak forest (Quercetum petraeae-cerris, with sessile and Turkey oaks) at MountAnna of Törökbálint, the other was the grassland at the edge of Tétény Plateau nearDiósd. A detailed vegetation structure study was formerly planned by the researchersfor evaluating the degradation resulting from the constructions. After two samplingsurveys the grassland site was destroyed and thus botanical data of this site are ex-cluded from this case study.
Botanical results
Monitoring higher plants on Mount Anna of Törökbálint
No significant differences were found in the plant species lists of 1990 and 1995 of themixed oak sample site. The slight fluctuation recorded here can be defined as normalfor this habitat. The appearance of some photo- and xerophilous species is worth men-
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tioning at most. Generally the disappearance of a species does not imply its extinctionfrom the area, because it may survive in hidden or hardly detectable form. However,striking changes could be observed in forest physiognomy and species mass relations(dominance) which both can be related to highway construction (the extent of changeswas inversely related to the distance from road).
The most visible damage was the treetop defoliation type of forest damage. The domi-nant tree species, the Turkey oak was primarily affected in this way. The occurrence oftreetop defoliation was more that 30% in the forest skirts of 10 to 20 metres wide, andwas sporadic in the inner parts (more 50–100 metres from the skirt). The herb layer re-sponded the most quickly to the changing light conditions: its cover increased to75–100%, which is significant if compared with the estimated 30–50% cover previ-ously. The biomass of several herb species increased greatly. Meanwhile some speciesbecame absolutely dominant (Poa nemoralis, and in less extent Dactylis polygama andAlliaria petiolata) most species seriously lost ground. Several new species emerged,some of them are especially disturbance tolerant species (e.g. Euphorbia cyparissias,
Muscari racemosum) while others – in a much less number – are rare protected species(e.g. Illyr buttercup, Ranunculus illyricus). Invading ruderal weed species were notfound to be characteristic although they can be found everywhere in the destroyed sur-faces close to the forest.
The above phenomena may lead to the following conclusions:
Significant changes occured in the forest climate and/or in the soil water regime to-wards drying within the 5 years of the study. Tree damage increase the drying processand/or vice versa. The identification of the reason of tree damage would need a com-plex survey, however, the above mentioned constraints must have a major importance.
Intensive increase of herb biomass, among them the nitrophilous poor man’s mustard(Alliaria petiolata) relates to eutrophication. It does not necessarily indicate direct nu-trient input but rather the possibly increased mobility of soil nutrient supply or the in-crement of nitrogen fixation capability of the soil as environmental conditions havechanged. Clarifying the background of the observed eutrophication would requirecomplex studies.
As a consequence of tree damage, an increase in biomass of the more slowly respond-ing shrub stratum (underwood) is expected parallel with the repression of herb layer, inwhich case the trends in species composition (biodiversity) can not be forecasted. Thiswill transform the forest physiognomy in a greater extent and thus will lead to changesin the fauna as well.
After all the construction as a single intrusion restructured the sample plot so much,that the great structural changes probably hide the other affects of the highway opera-tion (traffic) – certainly not including element accumulation in the nearby environ-ment. Exploring the abiotic background and future processes of the structural changescan be an interesting basic research aim, but does not fall within monitoring activities.
Linear surveys of roadside (grass verge) vegetation
It has to be mentioned preliminarily, that no similar research was done anywhere inHungary thus routine-like methods are not known. Consequently the study results maycontribute in some extent to the development of road shoulder studies as well.
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Chapter 5
The survey was done on June 5, in 1995, at an optimal phase of the vegetation (com-plete summer vegetation aspect with identifiable spring and autumn elements). Fullplant list was recorded for all sample sites. Rough biomass estimation was also carriedout for given species, i.e. a species was considered to be abundant if it covered 50–90%of the plant covered surface. Dominant was a species which occupied more than 90%of the plant covered surface. The following results were found:
The extreme heterogeneity of the sample refers to the less organized vegetation and toits random character.
Dimension of homogenous vegetation patches fall in the decimetre-metre scale whichis much less or is at around the characteristic area for the given species.
The plant ecosystem is unformed and unsettled, its structure is loose and no deeper in-vestigations of structure is worthwhile.
Trends in species composition are more interesting. The 109 recorded species can beclassified as mmber of the following community types:
• disturbance tolerant species of natural ecosystems (z, 38 species),
• weeds of abandoned and arable lands (p, 26 species),
• pioneer vegetation (weed-like, ruderal) of devastated surfaces (d, 18 species),
• nitrophilous weed communities (n, 11 species),
• cultivated species of plough-lands (k, 10 species),
• trampled weed communities (t, 5 species),
• species planted to cope soil erosion on roadside slopes (r, 1 species).
Despite that survey results were very different both in species numbers (ranging 0–42)and in species composition, the whole highway section can be characterized by a basicvegetation type. Eight species occur in more than the half of the sampling quadrats andwith one exception all of them were semi-dominant or dominant in several samples:
• Matricaria inodora (a wild camomile, d), in 13 samples,
• Polygonum aviculare (prostrate knotweed, t), in 12 samples,
• Lolium perenne (common ray, t), in 11 samples,
• Brassica napus (rape, k), in 10 samples,
• Festuca rubra (red fescue, r), in 10 samples,
• Lactuca serriola (wild lettuce, d), in 10 samples,
• Ambrosia elatior (ambrosia, p), in 9 samples,
• Apera spica-venti (a grass species, p), in 9 samples.
The above 8 species well reflect the origin of the flora of the road bench as well as itsecological characters and population dynamics.
The greatest group of the total plant list is the disturbance tolerant species of the naturalflora (i.e. the non obligate weeds). These species are usually not abundant individually.More numerous appearance is expected in areas where natural vegetation has survived
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road construction in a neighbouring or close habitat patch. However, some more rareplant species undoubtedly arrived to the sample sites “on the road”, e.g. the Vulpia bro-
moides spreading from Western Transdanubian and the Puccinellia distans the settle-ment of which is probably supported by the salt spreading on roads in winter.
Vegetation at the noise reducing walls (noise screens) is extremely poor, especially inthe sections where both sides of the road is protected against noise (12–13th km sec-tions). This fact is a definite evidence of colonization routes of road shoulders, i.e. thatcolonizing propaguls arrive mainly from lateral directions, while longitudinal coloni-zation direction is of much less importance (however, in the case of cultivated andsome other species this might be the prime migration direction). Poverty of the noisescreen feet vegetation can be caused by the unfavourable microclimate and by the ac-cumulating contamination.
Invasive species of Hungary as Apera spica-venti and Ambrosia elatior (ambrosia) arenumerous in road benches as well, in spite of the fact that this habitat does not fallwithin their ecological optimum. The significant factor is the seed input in their case,as well as in the case of Festuca rubra (red fescue), planted locally for avoidance ofsoil erosion and in the case of cultivated species expanding their area by transport.
As a summary, one may state that vegetation of the road verge suffers the most frompollution and has successful adaptation mechanisms. This vegetation is an ideal sub-ject for element accumulation monitoring, for genetic (enzyme polymorphism) inves-tigations and for studying the biochemistry of antidote to poisoning. Several abundantspecies of this habitat, like Polygonum aviculare (prostrate knotweed), Poa compressa
(Canada bluegrass), Chenopodium album (white goosefoot) have obvious morpholog-ical signs of high genetic diversity.
Zoological results
Quantitative analysis of avifauna, Mount Anna of Törökbálint
The breeding bird community of the Törökbálint site was characterised by the strongdominance of six species during the status survey (May, 1992). The blackbird (Turdus
merula) and the robin (Erithacus rubecula) were dominant on the ground and shrublevels, blackcap (Sylvia atricapilla) dominated shrub and canopy levels, golden orioledominated (Oriolus oriolus) only the canopy level while chiffchaff (Phylloscopus
collybita) and chaffinch (Fringilla coelebs) the canopy and the ground levels (the for-mer breeds, the latter partly feeds on the ground).
Several subdominant and colouring (glossy) species could be found on the area. Greattit (Parus major), blue tit (Parus caeruleus), song thrush (Turdus philomelos), treepipit (Anthus trivialis), great spotted woodpecker (Dendrocopos major) belong to theformer group. Correspondingly to their natural density, there are only a small numberof turtle dove (Streptopelia turtur), cuckoo (Cuculus canorus), green woodpecker(Picus viridis), jay (Garrulus glandarius) and long-tailed tit (Aegithalos caudatus) etc.Nightingale (Luscinia megarhynchos), wood warbler (Phylloscopus sibilatrix) andyellowhammer (Emberiza citrinella) live here on the periphery of their habitat require-ments.
There were no significant differences between the status survey of 1992 and the surveyof 1995. A slight alteration could be detected in the area closest to the road where 14
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Chapter 5
specimen of 6 species were recorded in 1992 while 7 specimen of 5 species occurred in1995.
Evaluating autumn migration and overwintering relations, the 1994 autumn survey de-serves interest: individual numbers of recorded species declined with the decreasingdistance as approaching the road. Only 7 specimen of 5 species (comparing to the totalbird checklist of 17) were recorded in the autumn, and 46 individuals of 9 species wererecorded in the winter survey.
Quantitative analysis of avifauna, Tétény Plateau sample site
Skylark (Alauda arvensis) was the dominant breeding species on the Tétény Plateausample site when the status survey was made in 1992. Between the skylark territoriesthe crested lark (Galerida cristata) territories are inserted along the cart-tracks.Wheatear (Oenanthe oenanthe), linnet (Carduelis cannabina) and red-backed shrike(Lanius collurio) live in the ditches and shrubs.
There were no great differences between the samples of 1992 and 1995 concerning ei-ther the breeding or the migrating bird species. The one third of the 3 hectares samplingsite situated closest to the road rather changed: from an edge of a steppe slope to aruderal, later to a recultivated area just at the side of the road. The other two third of thesample site – on higher elevations of the hillside and on the upland 15–20 metres abovethe road – remained intact. The grassland grazed by sheep provides suitable habitat forthe former grassland bird community after the construction as well.
Vertebrates run over on the road surface
The highway as mortality factor is significant for vertebrate populations living in habi-tats along the road. Primarily mammals fall victim to the traffic owing to their noctur-nal activity and to the sparse (insufficiently frightful) night traffic. Beside smallrodents (Micromys minutus, Clethrionomys glareolus) greater mammals as hare (Le-
pus europaeus), beech marten (Martes foina) or even stray domestic dogs are also runover.
Birds represent a relatively low ratio of run over animals, only 2 specimen were re-corded in the road section 0–14 km, and one more (a buzzard, Buteo buteo) at the 17thkm. The two victims belonged to the most frequently occurring species close to theroad: pigeon (Columba livia f. domestica) and house sparrow (Passer domesticus).Possible explanations of the low ratio of birds among vertebrates in accident are de-scribed in the following.
The four-lane wide road surface does not attract birds landing for feeding. Species andindividual number of birds is insignificant both on and nearby the road. The traffic ofthe day (daylight) is so dense, fast and dynamic that birds have no time and space forlanding on the roadside.
However, the crested lark (Galerida cristata) living frequently on the roadside adaptedvery well to the traffic and is able to evade even from faster vehicles by its mobility.
Summary
The completed five-year long monitoring study intended to follow the environmentalimpacts of the construction and operation of a motorway. It may serve as a useful basisfor planning future monitoring activities. The study sites can be considered “conflict
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areas” in terms of nature protection (the site at Diósd was destroyed totally, the othersite at Törökbálint suffered diffuse damage in a 20–30 metres wide zone). Similarly,both sides of the highway in a 20–50 metres zone requires specific interest and investi-gation in the future, and should be considered as conflict zone both considering botanyand zoology.
5.3.3. Corridor function (The role of linear infrastructures in the invasion of species)
Invasion is the process by which a newly introduced foreign species, but sometimes a nativespecies, starts sudden expansion and temporarily or steadily restructures living communities.Primary reasons of invasions were formerly the climatic changes. In the past decades the traf-fic and transportation had significantly accelerated these processes. Decrease of biodiversitywas proven in every case.
Direct background of the phenomenon is the growing effectivity of propagule spreading.Propagules (seeds, eggs, vegetative reproduction organs as gemmules, root and rhizomepieces) utilize the possibilities of linear establishments and gain such a high spreading poten-tial which was never seen before.
An important factor is the stability of the receiver ecosystems. In general, the pioneer associa-tions (grassy or nude banks, road shoulders, verges, construction areas) are more vulnerable toinvasion while fragmented semi-natural habitats resist invasion to a certain extent – dependingon their size and type.
Invasion was only slightly studied in Hungary, however, was early noticed. The first data pro-vider was Sándor Polgár who detected some dozen North American invasive species inGyõr–Sopron county after an American–Hungarian co-operative had increased its railwaytransportation volume. The most dangerous allergen species, the ambrosia (Ambrosia elatior)has also reached Hungary through this gate. Early spreading of ambrosia was reported – pri-marily from the Transdanubian region – by Ádám Boros and the species had gradually occu-pied the whole country. The western invasion is proven in this case.
No other publications were found about invasion, however, several manuscripts do exist. Oneof the most striking phenomenon was the mass damage of city road trees between 1996 and1999 (by horse chestnut leaf-mining moth Cameraria ochridella and by platan lace bugCorytucha ciliata). Localization of the damaged trees showed direct connection to linear es-tablishments.
Semi-natural vegetation may survive or can be reconstructed on the banks of old (80–150years old) railways, roads and channels. Invasion barely occurs here, however, these habitatshave a significant relict preservation function. The stabilizing and preserving functions werealso documented in the Kiskunság National Park (3rd district, alkali fields at Fülöpszállás nearSzabadszállás, Németh 1986–89).
Special studies were concerned on road verge vegetation within the frame of M0 expresswayBiomonitoring Program (see case study no. 1). The propagule spreading function of the shoul-der of the newly established road was witnessed primarily in the case of transported cereal spe-cies (wheat, barley, rape) and secondarily in the case of some native species requiring specialhabitat (Vulpia bromoides, Puccinellia distans).
The Hungarian Botanical Society started studying the spread of adventive species only in thelast 5–10 years. Within the National Biodiversity Monitoring Program, the pilot project, deal-ing with the spread of invasive species was launched last year. First results of this project will
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Chapter 5
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COST 341
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probably be utilized by nature conservation and road designer practice in about five yearstime, for example in the field of planning road shoulder and embankment vegetation as well asfor nature friendly maintenance techniques for road verge and shoulder vegetation.
5.3.4. Fauna casualties
The data resources are available in Hungary concerning effects of traffic and transport on thefauna selected information is presented in Table 5.3.4.1.
Table 5.3.4.1. Data resources regarding animal casualties
data collected by subjects of surveytime interval of data col-
lectioncollecting/recording
method and data reliability
qualified huntersgame species, country
levelcontinuous since 1998
annual game managementreport of qualified hunters
(hunting associations); reli-ability depends on the cca.1200 informators, can be
estimated to cca. 80%
public road direc-torates
accidents with human ca-sualties, country-wide
continuousimmediate data registration
on computer; reliable
insurance compa-nies
accident with loss insured,for every insured unit
irregular collection of data,by damage
record is different, depend-ing upon companies, on
damage survey forms until1998; reliability is doubtful
National Author-ity for NatureConservation,
Ministry for Envi-ronment
Biodiversity MonitoringProgram, 40 integrated
sites all over the country,mainly on protected areas
regular surveys of taxo-nomical groups since 2000,surveying time frequency
depends on animal or plantgroup and on localities
surveys by expert groups,data recorded and pro-
cessed on computer in thenear future; reliable
universities, re-search institutes,
NGOs
financed from differentsources, programmes deal-ing not/not only with frag-
mentation
irregular surveys, short,usually only few years
long programmes
research reports are fre-quently made without ref-erence study; reliability
varies
HungarianNatural History
Museum
data of differentprogrammes
continuous data registra-tion of taxonomical groups
of animals
digitalized data of reliablescientists
Invertebrates
There are roughly 42.000 animal species registered in Hungary, 99% of which are inverte-brates. However, effects of transportation on a major part of the Hungarian fauna were notstudied in details by any of the research groups. The single monitoring-type study was the onementioned earlier in case study no.1, with two study sites (described as well in case study no.2) at the 0–14 km section of the M0 expressway between 1992 and 1995.
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Chapter 5
Case study no. 2. INVERTEBRATE FAUNISTICAL STUDY OF THE M0 EXPRESSWAY,SECTION 0–14 KM
By O. Merkl
The construction of the studied section of the M0 expressway was started in the secondhalf of 1992. The road was opened in 1995. The aim of the investigations was to iden-tify the damages caused by the construction and operation of the studied expresswaysection on the natural values of the surrounding area.
Lead accumulation in diplopods
There is practically no difference in the lead content of samples from 1992 and from1995 (0.26–5.5 � g/g in 1992 and 1.3–3.9 � g/g in 1995). Though standard deviation ofsample 1995 was much less, it has no influence upon the fact that there was no signifi-cant change in lead accumulation in the past 3 years. It refers to (1) the insignificantamount of lead emitted by vehicles incorporated to plants, or (2) that the lead accumu-lation did not reach the consumers of fallen leaves until the study, or (3) the amount oflead emitted is unimportant.
Arthropod fauna of the soil surface
Analysis of the samples of pitfall traps showed that species dispersion in the inner for-est was more or less uniform in both sampled years (1992 and 1995). One may con-clude that there is no detectable effect of the road construction yet on the arthropodfauna of the undisturbed forest patches. In 1995 the species composition of the firsttrap (closest to the road) strongly differed from the further ones, because road con-struction and the consecutive tree felling caused drying out. The Megaphyllum unili-
neatum is the most frequent Diplopoda of xerotherm habitats and does not occur in theinner part of forests. Harpalus distinguendus, H. rufipes and Calathus ambiguus
carabids are typical indicators of disturbance. Amara aenea is a characteristic speciesof agricultural areas and abandoned lands.
Beetles living on foliage
One of the two sample sites (see site description in case study no. 1), the Törökbálintforest became weedy (indicated also by the numerous appearance of leaf-beetlesGaleruca tanaceti and Galeruca pomonae) and treetop defoliation could be detected.There was no other changes in the beetle community of the forest. However, in theother site at Diósd, the sampling site lost almost totally its former state. The vast degra-dation obviously affected the beetle community, e.g. the characteristic leaf-beetle spe-cies (Cheilotoma musciformis) of open, bare dolomite and limestone habitats could notbe recorded in 1995. On the plant musk thistle (Carduus nutans) growing in great num-bers on disturbed areas, a long-horned beetle (Agapanthia dahli) population lives inhigh abundances. The ground-beetle Calathus cinctus is characteristic for devastatedareas under antropogenous pressure.
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Amphibians and reptiles
Vertebrate fauna of Hungary has 556 species, 475 of which are terrestrial (438 of them are pro-tected) potentially affected by transportation (Figure 5.3.4.1.).
80–90% of vertebrate species that fall victim to cars, belong to amphibians and reptiles. Thecollision risk of four species belonging to amphibians and reptiles was studied at a countrylevel by the research groups of the Institute of RISSAC and of the Saint Stephan University ofGödöllõ within the frame of this COST project. Study results are shown in case study no. 3.
Case study no. 3. HABITAT VALUE AND TRAFFIC PATCH MAP
By T. Tóth, L. Pásztor and B. Bakó
Estimated/modelled distribution range map of amphibians and reptiles served as basisfor the map, because UTM distribution maps of 10×10 km grid size were not suffi-ciently detailed and the inventory of the studied species was not complete for the coun-try. The distribution ranges of the chosen species were estimated by creating models inthe scale of 1 : 100.000.
The following presumed environmental limits and measures were used in the model-ling processes:
59
Chapter 5
Figure 5.3.4.1. Number of protected and strictly protected animal species in Hungary (blue:protected species, yellow: strictly protected species).
Matrices were established for quantifying the quality (correctness) of models in whichthe estimated and the recorded occurrences were compared. The following table showsthe precision of models of species:
Model precision was very different for different species (Figure 5.3.4.1.). Species withan uncertainty factor below 0.1 were disregarded from the study, because their ecolog-ical modelling could not be accurate enough.
For representing traffic data on map, the traffic database of the Technical and Informa-tion Services on National Roads was used. This database was the source of the derivedmeasure: the road density weighted by traffic density for one square km (vehicle/day ×(km/km2) which measure shows the number of cars running 1 km within the 1 km2 gridcell a day, or the length (in km) of road sections with one vehicle/day traffic intensitywithin one grid cell etc.
Inventory status of amphibians and reptiles are shown on inset maps. Territory of Hun-gary can be covered by 1060 UTM gridcells of 10×10 km. From 375 cells there are oc-currence data for amphibians and reptiles, thus their inventory status is 35% forHungary.
Summary
Comparison of the national habitat values and the traffic map show that the experimen-tal methodology is applicable. However, no general conclusion can be made on thebase of these four species mainly because they range is restricted more or less to themountainous areas (see the table about their ecological requirements and the model-ized distribution maps). Species with the highest collision risk (for example commontoad Bufo bufo, agile frog Rana dalmatina, edible frog Rana esculenta) were lackingappropriate data and thus were omitted from the analysis and consequently the conflict
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COST 341
Yellow-belliedtoad
(Bombina
variegata)
Common frog(Rana
temporaria)
Aesculapiansnake
(Elaphe
longissima)
Sand lizard(Lacerta
taurica syn.Podarcis t.)
Soil type sandy
Annual mean temperature < 10.5 °C < 9.5 °C < 10 °C
Average annual precipitation > 650 mm < 650 mm > 650 mm
Habitat forest forest forest
Relative relief 50–150 m/km < 50 m/km 50–150 m/km
Species Uncertainty factor Total precision(%) Cases recorded (%)
Common frog 0.28 92 74
Yellow-bellied toad 0.21 89 69
Aesculapian snake 0.12 89 49
Sand lizard 0.11 82 63
map of this study does not show the notorious sites of running over amphibians e.g. thecircle route of Lake Fertõ or the Ipoly region. For the interest of the usability of maps inscale 1:100.000 as well as the accuracy of ecological modelling has to be increased.Thus the necessity of the gradual inventory of the remaining 65% cells is obvious.
61
Chapter 5
Distribution according to the model
Present reported distribution
Formerly reported distribution
5.3.4.1a. Distribution of yellow-bellied toad
Distribution according to the model
Present reported distribution
Formerly reported distribution
5.3.4.1.b. Distribution ofcommon frog
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COST 341
Distribution according to the model
Present reported distribution
Formerly reported distribution
5.3.4.1.c. Distribution of aesculapian snake
Distribution according to the model
Present reported distribution
Formerly reported distribution
5.3.4.1.d. Distribution of sand lizard
63
Chapter 5
Num
ber
ofsp
ecie
s=
SN
, tra
ffic
dens
ity
=td
SN
<2,
td<
500
SN
<2,
500
<td
<50
00
SN
<2,
5000
<td
SN
=2,
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500
SN
=2,
500
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<50
00
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=2,
5000
<td
SN
>2,
td<
500
SN
>2,
500
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00
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>2,
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Fig
ure
5.3
.4.1
.H
abit
atva
lue
and
traf
fic
dens
ity
patc
hm
ap.
Birds
The oldest protected group as well as the most numerous group of the vertebrate fauna of Hun-gary are birds. The statement, that road environs are suitable reproduction habitats for birds issupported by our case study no. 4 about birds fallen victim to traffic. Among victim speciesthere are numerous species breeding on road verges and at ditch sides (terricol species as forexample stonechat Saxicola torquata, whinchat Saxicola rubetra, crested lark Galerida
cristata), breeding on trees of tree-lines and forests at the road (arboricol species as for exam-ple collared dove Streptopelia turtur, blackbird Turdus merula, red-backed shrike Lanius
collurio) or in bushes (fruticicol species as for example wood pigeon Columba palumbus,green finch Carduelis chloris, chaffinch Fringilla coelebs, goldfinch Carduelis carduelis,magpie Pica pica). If older trees are also living in the vicinity, than hole nesting species(dendricol species, as for example starling Sturnus vulgaris, house sparrow Passer domes-
ticus, tree sparrow Passer montanus) may fall victim to cars as well. The road surface and theclose vicinity is suitable for collecting nest building materials (Schmidt 1986).
Beside providing breeding habitat, road surface and road environments have important foodresource role as well. The road and its vicinity have special microclimate which may be morefavourable – in some aspects – than the natural environment. Road surface warming up fasterand retaining high temperature for longer time attracts arthropods (having environment de-pendent body temperature) and their presence offers an outstanding hunting possibility for in-sectivorous birds. Utilization of food resource is even better on roads with traffic becausearthropods died on windscreen or on grille are more easily collected (with less energy input)than hunting for living prey, resulting in a better survival strategy. Crested lark (Galerida
cristata) was recorded to feed frequently its young with insect bodies collected this way(Schmidt 1986).
Human activities as the application of deicing salt, trampling, or the lead emission formerly in-creased the presence of weed species on road verges, among them species (e.g. variousPolygonum sp.) with seed production important for granivorous birds. Cereal seeds fallingfrom crop transporters also offer rich food sources for them. Some birds (for example rooks)may feed on wastes thrown from cars. Certain birds of prey prefer hunting for small mammalsor insects crossing roads (for example the European kestrel Falco tinnunculus at daylight, orthe little owl Athene noctua at night). Finally the animal carcasses along the roads attract somebird species as common buzzard (buteo), magpie, hooded crow (Corvus corone cornix), butthere are records of white stork (Ciconia ciconia) feeding on run over frogs and toads as well(Onuczán 1992). Birds may warm up on road surface on cool mornings or they may bath inwater collected on roads after rain showers (Schmidt 1986).
Beside the above mentioned breeding and feeding habitat functions (mostly positive roles) ofroads the negative effects have to be mentioned as well. The most important is the barrier ef-fect of roads which can be observed at fenced motorways or even at roads leading close to wa-ter bodies. Waterfowl breeding or feeding further from water bodies and thus crossing the roadis necessary, may be actually restricted by intensive traffic – for example if they rear youngsmoving only on the ground. Sandpipers are found most frequently in this situation but avocet(Recurvirostra avocetta) was also recorded as isolated by road (Kasza 1994).
Grey or asphalt surface may be misleading in foggy weather or at night and birds land on roadinstead of water surface. Grey heron, coot and bean goose were recorded landing onto theroads of Sopron, a city in West Hungary at the main migration route of waterfowl. Many wa-terfowls (among them mallard, garganey, coot, lapwing) were observed on the road sur-
64
COST 341
rounded by middle-aged beech forest of Brennberg valley close to Sopron (Kárpáti 1987).Their stay on the road mostly leads to their death.
Among the negative effects of roads on birds we have to emphasize the bird damages causedby vehicles. These damages may be:
• occasional ones effecting great number of birds, or
• the continuous perish caused by the permanent traffic.
An example of the occasional damage was the death of some hundreds swallows at the DanubeBend (21. July 1981). Those birds were hunting above the road in the cool weather, mainly in-experienced young swallows (Nagy 1981). In the vicinity of pheasant rearing farms the possi-bility of mass-collision is increasing if pheasant density is high.
Birds occupying various habitats at roads are living in continuous collision risk. Bird casual-ties are primary related to their feeding activity along roads.
Case study no. 4. EFFECT OF TRAFFIC AND TRANSPORTATION ON BIRDSIN HUNGARY
By S. Faragó
Introduction
A survey of bird road kills has been carried out on the basis of mainly literature data,originating from 8 road sections around Hungary.
All surveys were made in summer of different years between 1978 and 1990.
It can be stated, that on the base of the eight study transects the granivorous and the in-sectivorous species have the highest collision risk. Species mostly endangered areranked as follows (percentage valkues of occasions are given): house sparrow (Passer
domesticus) – 31.7%, swallow (Hirundo rustica) – 11.3%, tree sparrow (Passer
montanus) – 10.9%, pheasant (Phasianus colchicus) – 9.4%, blackbird (Turdus meru-
la) – 7.1%, goldfinch (Carduelis carduelis) – 4.7% and red-backed shrike (Lanius
collurio) – 4.2%. There are occasional cases of unexpected species as for example thestone curlew (Burhinus oedicnemus) or the water rail (Rallus aquaticus).
Another study was made close to Budapest in 3 consecutive years for a network ofroads of about 120 km. It can be concluded that dominance ranks are changing in timeand the frequency of insectivorous species is decreasing. The number of casualities in-creased only in the case of tree sparrow, a generalist species. Beside tree sparrowshouse sparrow, red-backed shrike and goldfinch die most frequently along roads as thethree-years average shows.
Management recommendations
Bird damages can be significantly lowered by satisfying certain conditions, namely:
• wetland areas have to be avoided by new roads,
• reconsideration of planning guidelines for tree rows: increasing the plantingdistance from the road, planting only one side of the road (decreasing avenue crossflying),
65
Chapter 5
• decreasing the amount of cereal and other agricultural product lost during trans-portation, thus decreasing the abundance of granivorous bird and mammal speciesand that of their predators,
• regular cleaning of waste and preventing littering along roads,
• systematic removal of animal cadavers as frequently as possible,
• reconstruction of attractive habitats further from the road,
• regular mowing or clipping of road verges 1–2 m wide for preventing the seedproduction of weeds.
Mammals
Several publications report about effects of transportation on mammals, some of them wereshown in chapter 4.2. Systematic survey at a national level, however, was only made two times(in 1996 and in 1999) regarding the non-protected game species.
Hunting association territories were the reference units in both surveys thus the results reflectthe collision risk of different road sections. Owing to the lack of detailed data (accidents in re-lation to wildlife fences etc.), no management recommendations can be derived from the stud-ies.
One of these studies analysed the game collision data from 1995 (by the Environmental Man-agement Institute, consigned by the Ministry of Agriculture). Area coverage was about 35% ofHungary’s road network, thus the survey can be considered representative for the country. Re-sults of the study are described below (Pallag 1996).
Strong correlations were found between collision numbers and population size in the case ofroe deer and red deer. Estimated total collision number of red deer was about 450–500 (popu-lation number is 50.000 individuals) and of roe deer was about 3500–4000 (population num-ber is 233.000 individuals) for the investigated area in 1995.
No correlation was found between population size and collision number in the case of otherbig game species (wild-boar, fallow deer, moufflon). Collision risk of wild-boar and moufflonis in relation with the character of the adjoining habitat along roads. Significant part of our fal-low deer population lives within fenced areas (game parks etc.) thus running over a fallowdeer is a rare event countrywide.
A second data analysis (of data from 1997–1998) was made at the Sopron University. Resultsare shown in case study no. 5.
Case study no. 5. EVALUATION OF THE GAME ROAD KILLS BASED ON STATISTICSOF 1997/1998
By A. Bidló, S. Faragó and G. Kovács
Introduction
The data of game road kills collected and summed up by local hunting associationswere processed. 1030 of the total 1200 rifle clubs have sent their summed records ofgame collision for the seasons 97/98 and 98/99. The submitted summaries do not seemto be reliable in the case of small game (hare, pheasant) as these data varied greatly.
66
COST 341
The following factors were also used during evaluating the data: game populationnumber, bag sizes, road network, number of motorized vehicles, forest coverage.
Results
Almost half percent of the Hungarian red deer population dies in accidents. Analysis ofred deer casualties county level, showed that number of accidents is primarily the func-tion of population size, or the forest coverage, that is close correlation with populationsize. No relation was found between deer casualty number and the length of roads ortraffic intensity.
Fallow deers scarcely appeared in collision statistics, about 0.1% of the country popu-lation was involved. No statistical tests could be processed owing to the very lowcases. However, on the base of the reports the relation between collision number andbag size seems to be stronger than that of the population size.
Roe deers in accidents accounted for almost 1% of the Hungarian population. Factorsaffecting casualty numbers are different for bucks from that of does and fawns. Its rea-son is their different behaviour. Ratio of bucks, does and fawns was more or less simi-lar to the sex and age distribution of the total population.
Moufflon was reported most rarely among big game species. About 0.5% of the totalpopulation fell victim to traffic during the studied time period. The law risk can be ex-plained by the low density and by the behaviour of this species.
Run over wild-boars account for 0.4% of the Hungarian population. No relation wasfound among population size and roadside mortality of boars and piglets, nor betweenforestry cover and roadside mortality.
Summary
Counties were possible to distinguish on the base of the data received. The most impor-tant factor affecting collision risk was the population density in most species – as it wasexpected.
5.3.5. Barrier effects
The following case study demonstrating the barrier effects of linear infrastructures was sup-ported by the present COST project.
Case study no. 6. CONFLICTS BETWEEN TRANSPORTATION INFRASTRUCTUREAND ECOLOGICAL CORRIDORS IN FOREST ECOSYSTEMS
By D. Bartha, A. Bidló and G. Kovács
Introduction
For the purpose of investigating the effects of public roads on forest ecosystems theVitnyéd section of the main road No. 85. (from Gyõr to Sopron) was designed. Theroad is open for decades. There is a forest on the northern side of the road with a typicalof the mixed oak community (Turkey oak and robur, Quercetum robori-cerris) of theLittle Hungarian Plain. Three forest stands have been selected along the road:
67
Chapter 5
• old forest stand of the northern side,
• young forest stand of the northern side, adjacent to the former forest,
• similarly young forest stand of the southern side of the road opposite to the formerone.
Results
No great damages of the habitats could be found along the road. No lead accumulationof the vegetation was measured at this site, which effect was often reported in publica-tions.
Botanical investigations supported the significant barrier effect of the road in the casespecies with animal transferred propagules. The proportion of fruits and seeds crossingintestinal tract (endozoochor), transported on body surface (epizoochor) and carried byants (myrmekochor) is much lower on the other side of the road than in the northernside (Figure 5.3.5.1.). Ratio of self transferred species is also lower there. However,the road is a weak barrier for wind spread species. It is worth noting, that the major partof our weeds are wind-spread (anemochor) species.
Wind spread (A, anemochor) and man-transported (At, antropochor) species are mostabundant in forest belt close to the road. However, the more sensible ant-carried (M)and epizoochor (Ep) species occur here in a much lower abundance than in forest partsfarther from the road.
Proportion of species indicating naturality is more or less the same in the old and in theadjacent young stand, thus there is no barrier for the spread of these species (Figure5.3.5.2). However, the site on the other side (south) side of the road is poor in naturalspecies (community constituant and accidental species) demonstrating the barrier ef-fects of the road for this species group. The parallel increase of species indicating deg-radation (weeds, cultivated, alian, disturbance tolerant species) was observed at thissite.
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COST 341
Figure 5.3.5.1. Types of seed propagation of the three selected stands
There is a gradient of the degrading effect of the road as a function of distance from theroad. Only two-third of the characteristic secondary species of associations can befound in the forest belt close to the road, while the ratio of weed species is three timesgreater than in the forest parts farther from the road.
Also owing to the edge effect, shrub species are growing in a higher ratio in the forestbelt close to the road. The abundance of annual and biennial species that are ready tooccupy devastated areas, is greater here whereas the ratio of perennial herbs (mainlyhemicryptophites) is higher farther from the road. The greater habitat disturbance closeto the road is indicated by these results as well.
5.3.6. Overview of environmental bottlenecks
Conflict situations in habitat fragmentation – an overview
Habitat fragmentation conflict maps
Roads, pipelines, cables, channel and allies, altogether the linear infrastructural establish-ments may cause conflicts in many ways which conflicts threaten the survival of species andhabitats of outstanding importance (rare or protected ones). As by our definition, habitat frag-mentation conflict maps show the conflict sites and situations between linear infrastructureand different habitats. Consequently these maps are made of two different data type. Factorsinducing habitat fragmentation are the ones, species and habitats threatened by fragmentationare the others (see Chapter 4.2.). The factors inducing habitat fragmentation, among them roadposition, traffic intensity, physical shape of road network and others are found on topographi-cal maps, road maps and traffic maps. The occurrence data of species and habitats threatenedby fragmentation can be found on protected area maps, and distribution maps. Conflict seri-ousness can be evaluated only by examining them simultaneously.
Two approaches (thus two investigation methods) were chosen for this purpose in Hungary:
69
Chapter 5
Figure 5.3.5.2. Nature conservation category values (Simon 1992) of the three stands
We investigated the movement behaviour and migration data of amphibians and reptiles. Re-sults are shown on Figure 5.3.4.1. National habitat value and traffic density patch map
(see case study no. 3). The following databases were used for compiling the map:
• Reptile and amphibian distribution maps in UTM grid, cells of 10×10 km. (source: OakNature Conservation Society, Gödöllõ),
• Corine Land Cover database (source: Ministry for Environment),
On the other side, we defined the fragmentation susceptibility category of habitats togetherwith the state of vegetation and the role of habitat in the preservation of animals of outstandingimportance (e.g. protected species). We demonstrate this method on Figure 5.3.6.1. “Frag-
mentation conflict map”. Data sources were:
• Corine Land Cover,
• Agro-topographical database (Environment and Landscape Management Institute of theSt. Stephen University, Gödöllõ),
• Forestry management maps for areas adjoining to settlements (University of Sopron),
• Estimated actual habitat map of the Hungarian grasslands (Ecological and BotanicalResearch Institute of the Hungarian Academy of Science and BirdLife Hungary),
• Traffic density (Technical and Information Services on National Roads of the Ministry ofTransport, Communications and Water Management).
The first step of map design procedure was the completion of the grassland actual habitat mapwith forest information. The forestry management maps were then collated with the advancedgrassland map with the help of the Research Institute for Soil Science and AgriculturalChemistry of the Hungarian Academy of Sciences (“Estimated actual habitat map of Hun-gary” Figure 5.3.6.2.).
Fragmentation parameters of the are discussed in chapter 5.3.1. and Table 5.3.1.
On the base of susceptibility classes of Table 5.3.1, the following susceptibility rank was cre-ated for the habitat categories:
Habitat type Susceptibility
Man made (built-up, ploughland etc.) 0
Less sensible 1
Medium sensible 2
Very sensible 3
The enclosed fragmentation conflict map of Hungary shows the importance of conflict in 1×1km grid cells (map 5.3.6.1.). A cell of this map indicating less susceptible habitat means thatmean susceptibility was below <1.5, a cell indicating medium susceptible habitat means an av-erage susceptibility between 1.5 and 2.5, while very susceptible cells means an average sus-ceptibility >2.5.
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COST 341
71
Chapter 5
Tra
ffic
dens
ity
=td
Les
sse
nsib
leha
bita
t,td
<50
0
Les
sse
nsib
leha
bita
t,50
0<
td<
5000
Les
sse
nsib
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bita
t,50
00<
td
Med
ium
sens
ible
habi
tat,
td<
500
Med
ium
sens
ible
habi
tat,
500
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<50
00
Med
ium
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ible
habi
tat,
5000
<td
Mos
t sen
sibl
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t,td
<50
0
Mos
t sen
sibl
eha
bita
t,50
0<
td<
5000
Mos
t sen
sibl
eha
bita
t,50
00<
td
Fig
ure
5.3
.6.1
.H
abit
atfr
agm
enta
tion
conf
lict
map
.
72
COST 341
Fig
ure
5.3
.6.2
.E
stim
ated
actu
alha
bita
tsof
Hun
gary
.
The reliability of the two conflict maps will have to be checked in the future by field surveys.
Maps will need to be revised as necessary. These conflict maps have to be used exclusively for
planning tasks at a regional level. Detailed wildlife protection studies have to be made at the
level of study plans or realisation plans.
5.4. SUMMARY
Relatively few researches dealt with habitat fragmentation effects of linear infrastructures –
among them of roads – in Hungary. Their results show significant differences between roads
depending on their size and traffic intensity. The effects of narrow (paved) roads with little
traffic is insignificant if compared with motorways or expressways the fragmentation effect of
which is really strong. Botanical investigations and demonstrated that wider roads do not (or
only slightly) alter the vegetation further from the road but do hinder the spread of propagules.
This effect leads to a poorer vegetation in the long-run. Roads seem to be more important in
the context of the spread of the invasive weed species and other disturbation tolerant species
which all utilise roads for invading new habitats.
Environmental effects are more complex in the case of animals. Contrary to the expectations,
significant lead accumulation was rarely found in animals (and plants) living along roads.
However, segregation is well demonstrated in certain animal groups (mainly in amphibians)
where road kill of animals is so high, that it surely affects population dynamics and demogra-
phy. Fenced motorways similarly segregate big game populations. We have less knowledge
about insects but the fact that wider roads distract several insects (even if they fly well) is well
known and thus roads hamper the movement of these species.
Comparing to Western Europe, establishments to support animals to cross roads (frog tunnels,
game bridges) have only been built during the part 10–15 years in relation to the development
of the motorway network. The study of animal passes showed that animals mainly do use them
and that certain modifications are necessary in their design in the future.
73
Chapter 5
Legend for Figure 5.3.6.2.
mountain oaks with sessile oak and tomentose oak dominance,canopy openings and clearings are frequent
Xerophilous mountain oak forests, usually of Pannonian types with turkey and sessile oaksbut sometimes monodominant undistinctive plantations
mesophilous hornbeam-oak forests of hilly and mountaineous areasMesophilous closed beech forests on plain, hilly and mountaineous areasmesophilous closed canopy mixed forests on plain and hilly areas, hygrophilous lowland oakforests of floodplains, and lowland steppe forests all dominated by pedunculate oakWillow groves: softwood forests of floodplains and sometimes undistinctive plantations ofhybrid willow varietiesbog-type or down-stream alder and birch groves
robinia plantations
hybrid poplar plantations
other deciduous forests and plantations (purple oak, maple, ash, elm, walnut, cherry, sorb-tree)pinewoods (mainly Scotch pine plantations but some semi-natural and natural stocksin western and south-western Transdanubia)
black pinewoods primarily on sand and dolomite
dry pastures and dry grasslands of eroded hill surfaces on rocky,gritty or earthy substratum
dry pastures and dry steppe-like grasslands of hills and mountains,spontaneously becoming bushy locally, abandoned vineyards and orchards onrendzina,vegetation of clearcuts, rocky grasslands and abandoned ploughlands
loessy grasslands (steppes) of plains and hills, sandy grasslands and abandonedvineyards/orchards on calcareous meadow and floodplain blackearth, onblack-earthy sand, on black-earth brown and on brown forest soils; sometimeswet or alkaline grasslands
semi-arid and dry pioneer and herb vegetation of clear-cuts and abandonedplough-lands on brown forest earth, on erubasic and on ranker soils
mesophilous grasslands of clear-cuts and abandoned arable lands on acidforest soils (no podzols) with loam content
open grasslands on sandy soils, juniper-white poplar groves on sandy soil,abandoned ploughlands and vineyards on sand-drifts or sandy soils with completeor eroded humus layer
alkaline grasslands of the Danube-Tisza Interfluve on solonchaks and solonetz soils
ancient alkaline grasslands, or secondary puszta vegetation of former floodplains(dried-out); both on meadow solonetz soil, or on meadow black-earth with asubsoil salty or solonetz layer, or on meadow solonetz becoming steppe
drying peat-meadows and semi-alkaline marsh-meadows (Danube-Tisza Intefluve),or alkaline grasslands (beyond the Tisza) on solonetz meadow soil
meadows of forest clearings with stagnant water (polder), peat-meadows andabandoned ploughlands all on pseudogleyic brown forest soil
polder meadows, sedge meadows and marshes of former and existing floodplainsor of areas with naturally high groundwater table; all on meadow soil, onmeadow-type or young alluvial soil or on the soil of former wet forests
former or existing fen vegetation: peat-meadows, fen-like sedge-vegetation,dried up fen vegetation; all on peat-meadow soil or on plain fen soil
Former or existing fen vegetation: dried-up fens, weedy wet (mesophilous)grasslands and fen remnants on reclaimed and divided plain fen soil
Chapter 6. Traffic safety in relation to animal casualties
Altogether 10.340 personal injury accidents happened in 1998 according to police registry (ta-ble 6.1.). Road Offices record only personal injury accidents (estimation for total accidentnumber is about tenfold), data of animal are not recorded. Our database made of rifle club re-ports can not be considered as complete (see Case study no. 5). A study result – part of the re-search programme of the Technical and Information Services on National Roads –demonstrated that among 1303 road animal casualities in 1997 and 1998, 692 affected animals(i.e. greater mammals in this case) at outskirts of settlements (Vlaszák 1999). A part of themare dog or cat injuries, and consequently does not belong to casualities originated from con-flicts between linear infrastructures and ecological networks.
Table 6.1. Personal injury accidents on national roads, 1976–1998.
Road categoryAccident numbers
1976 1980 1985 1990 1995 1996 1997 1998
Motorway 100 68 138 226 315 320 290 376
Expressway 84 51 32 100 62 56 37 37
Primary road 2370 2115 2083 3455 2277 1914 1931 1984
Secondary road 339 3218 3549 4969 3124 2930 3123 3279
Main network 5893 5467 5802 8750 5778 5220 5381 5676
Side network 4553 4730 5258 6881 4353 3993 4167 4664
Sum 10446 10197 11060 15631 10131 9213 9548 10340
Source: Main data of roads, Ministry of Transport, Communications and Water Management, 1998
Studies on the involvement of game animals in car accidents estimate game collisions of about4–5 thousand cases a year (Pallag 1996). Smaller vertebrates (birds, small game species, am-phibians) can certainly also cause accidents, the dimension of which is estimated to exceedthat of big games. About 4–5% of personal injury accidents is attributed to vertebrate animalroad kills. This means about 400–500 cases yearly, a number high enough to be worth consid-ering from human safety point of view.
The intension of saving human life appears in the 55/96 Act of Protecting Game Animals,Wildlife Management and Hunting as well. The Fifth chapter of the law states that damagecaused by game animal is to be compensated, among them the damage of running over a gameanimal on road if the accident is directly caused by hunting or by a badly designed wildlifemanagement (e.g. a feeder placed too close to the road, closer than 100 m). Obviously thehunter is maximally interested in conflict resolution between game animals and road network.This interest is especially important for economic aspects if we consider the significance ofhunting incomes for the country. The income in 1998 of the sector was 0.67 billion HUF(Wildlife Management Database, 1999). Trophy quality of the Hungarian red deer and roedeer population is in the first–second place in Europe.
After enacting the law, the hunting right holders recorded and submitted data (within their an-nual wildlife management report) first in 1998 about game animal damages caused by traffic.Relations between big game populations and road kill numbers are demonstrated in Table 6.2.
75
Chapter 6
Table 6.2. Population size and road kills for selected game for 1995 and 1998.
Game species
Estimated popula-tion size
ShotDeath other than of
shotEstimated collision
numbers
1995 1998 1995 1998 1995 1998 1995 1998
Red deer 50.063 74.053 21.825 20.105 1755 1548 257 361
Roe deer 233.367 269.060 37.890* 37.894* 7176 6977 1566 2040
Wild-boar 39.389 65.621 34.979 48.481 – 2278 163 220
* Note that data are by admission. Considering population size and demography variables of roe deer theabove data are underestimated.
15% of natural death (other than shot) of red deer was actually car accident in 1995, and colli-sion risk increased up to 23% until 1998. The trend is similar for roe deer (from 20% to 30%).The increasing collision risk is certainly the result of motorisation.
Future analysis of accident statistics is extremely important regarding wildlife protecting mea-sures. We can not disregard the result of the case study no. 7 about the efficiency of gamepasses, namely that roe deer kills still happen, however, M1 Motorway is supplied with wild-life (red deer) fence. While emphasizing the big game habitat segregation effect of wildlifefences the further study of wildlife protection measures is recommended.
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Chapter 7. Compensation measures to reduce effects
7.1. INTRODUCTION
Environmental impact studies are obligatory in case of a number of investment types since 1.January 1985 in Hungary. The EEC Council Directive No. 85/337/ EEC was released in thesame year on assessing the environmental aspects of certain public and private establishments.The Council Directive recommends the harmonisation of content requirements of Environ-mental Impact Assessments (EIA).
Aims of EIA are to define, to estimate and to evaluate all expected significant environmentaleffects of the planned activity and consecutively to influence decision making in the realisa-tion process. EIA has usually preparatory and detailed investigation phases which are fol-lowed by environmental audit as necessary.
Since the EIA regulation, road designers became increasingly involved in planning preserva-tion measures. More and more wildlife managers (known to be mostly familiar with gamepopulations of a given area) were included into the planning processes. The EIA decree forceddesigners to elaborate routes with the least conflict and to collaborate actively with the expertsof nature conservation administration during the planning phase. The following chapters dealwith possibilities of decreasing/mitigating the nature damaging and habitat fragmentation ef-fects of linear networks.
7.2. POSSIBILITIES OF AVOIDING HABITAT FRAGMENTATION
First of all distinction between the existing and the planned linear infrastructures regardinghabitat fragmentation is necessary. In the case of existing infrastructures the measures to betaken have only moderating role (for example the plantations to raise amenity value or the am-phibian tunnels), although the environmental law obliges effective mitigation measures of en-vironmental damages in the case of existing establishments as well. Paragraph 73. states that:for the purpose of revealing and recognising the environmental effects of a given activity andof suitably controlling the conformity to environmental requirements, an environmental im-pact audit has to be made. However, practice is different in the area of linear infrastructural es-tablishments. The competent authority (here the competent environmental directorate) mayoblige investors to audit activities in case of company ownership change or a great investmentpresumably affecting at least a microregion with environmental pollution (air, water or soil),but no such example is known for roads.
Preventing fragmentation in the planning administration
Interests of preventing fragmentation effects of roads or linear infrastructures in general canbe asserted in different planning phases and levels. Prescribed recommendations of regionalplans can be realised differently on the different levels of the planning hierarchy.
The Regional Planning Framework of Hungary (OTT) deals with central administrative (gov-ernmental) tasks. Regional policy plans of priority regions (national parks, some protectedlandscapes, Balaton recreation area and others) are partly belonging to OTT and partly tocounty plans. Beside national provisions county plans contain regional tasks as well.
Regulations of regional policy plans are finally defined and refined in the local policy plans ofsettlements. Greater investments are obliged to produce EIAs.
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Primary purpose of making a preliminary environmental impact assessment is to register,to compare and to assess the environmental impacts of the different route options and techno-logical versions as well as laying the foundations of a detailed environmental impact study.
The detailed environmental impact study (EIS) describes the present and forecasted state ofthe environment with and without the planned investment in relation to its activities. The de-tailed EIS gives recommendations for mitigating or preventing expected environmental dam-ages as well as for the controlling/monitoring methodology of the investment operation and itseffect after abandonment.
The method of searching for corridors, poor in conflicts
The most effective measure to avoid habitat fragmentation effect of new linear infrastructuresis selecting the best route. The plans of the past 10–15 years have resulted in numerous suc-cessful examples of this strategy.
Following an example of Germany the digitized planning model of conflict-poor corridor wasintroduced in the beginning of the eighties, during the planning phase of the peripherichighway of Budapest (M0 expressway). The methodology of this planning model rests uponthe estimation of sensitivity of land cover patches in relation to a wide range of environmentalconstraints. A 2–6 km wide transect including the planned route is analysed from this respect.A synthesis of sensitivity estimations is the next task for the investigated environmental ef-fects. Finally, the route is defined by planners to avoid the most sensitive areas. Beside theabove mentioned peripheric highway of the capital, this methodology was used in other greatplanning tasks as for example the M2 expressway, the expressway connecting the M0expressway and M3 motorway, the M6 motorway section from Dunaújváros to the southerncountry border (Figure 7.2.1.).
Transferring/transplanting populations of protected species
It can be stated, that transplantations of protected plants raises numerous problems and islikely to fail. Transplantations are to be applied only in the last resort. Though protected plantspecies of Hungary can easily be maintained in gardens, the establishment/reconstruction ofnew populations in the field is seldom successful. Instead of attempting species transplanta-tion, its habitat should be preserved.
Translocating a biotop
Translocating an association has a better chance of success. However, this solution is ratherexpensive. There are several successful Western European examples for translocation, andthere is one Hungarian example as well from 1998. A swamp meadow of high value wasthreatened by total destruction (filling up) during the enlargement of the Zalalövõ railway sta-tion at the new Hungarian–Slovenian railway line. Among other protected species, the globetrollius (Trollius europaeus), a liliom (Hemerocallis lilio-asphodelus), the Siberian iris (Iris
sibirica) and the maiden pink (Dianthus deltoides) occurred there. Snakeweed (Polygonum
bistorta) was also found in great abundances (this species can be very abundant in wet mead-ows of Western Europe but is rare and protected in Hungary). The competent national park di-rectorate authorised the enlargement of the station with the condition of translocating theswamp meadow together with the broad-leaved tall herbs’ meadow (about 1.7 hectares alto-gether). A degraded meadow with smooth three-ribbed goldenrod (Solidago gigantea) of sim-ilar water regime to the original habitat was fortunately found in a distance of 300 m. Astep-by-step accomplishment was planned by nature conservation experts. After finishing theground preparations, vegetation was cut out in 1×1 square metres by a special sod-cutter ma-
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Figure 7.2.1. Selecting the conflict-poor corridor in the vicinity of Szekszárd. Legend: red =very sensitive, yellow = medium sensitive, green = less sensitive, rest = non-sensitive. Source:UNITEF, 1983.
chine and translocated. Sods were placed in their original sequence. The monitoring survey ofthe new habitat found in 1999 that the rare species survived in their original abundance and nosignificant degradation was registered.
A similar sodding preserved the very valuable drying peat-meadow with Molinia (an associa-tion called Molinietum) from degradation. Eight parallel gas pipelines of the natural gas re-source in the Õrség region was planned to cut through the habitat along the Kerka creek. Noother solution was found and finally the meadow was transplanted in a 20 m wide and 200 mlong strip. After installing the pipelines, all sods were replaced to their original site. Themethod proved to be successful. The vegetation sprouted similarly to its former status andsome populations of protected species even became more numerous. On the short section,where no sodding was accomplished a totally degraded weed association with tansy (Tanace-
tum vulgare) emerged.
Nature conservation principles of designing routes
During the planning process of linear infrastructural establishments the objectives of expertscompiling nature conservation parts of the plan are “beside ensuring the survival of rare andendangered species, the long term preservation of the natural organisation of living communi-ties and maintaining the complexity of biological and ecological interrelationships” (Török1995). Ecologist must actively participate in raising public awareness of the fact, that the con-servation of nature has to be asserted even beyond the fences of protected areas.
Ranked wildlife conservation aspects of route designation are as follow:
• no linear infrastructure is allowed to cross strictly protected areas,
• linear infrastructure can be designed on areas protected on national or local level with theapproval of the competent nature conservation authority;
• linear infrastructure can never or only exceptionally cross the habitat or site of strictlyprotected species,
• the so-called “natural areas” (prepared for designation or with important natural values)have to be treated with care,
• protected habitat types (“ex lege” protection, as for example fens or alkaline habitats)deserve as much attention as possible,
• generally the most favourable solution in crossing valuable natural habitats is the one thatleaves the greatest unbroken area untouched,
• ecological corridors have to be treated carefully, irrespective their continuous or “steppingstones” character.
7.3. OVERVIEW OF MITIGATION MEASURES
Suggestions for mitigation measures can already be part of the planning phase of road designand later that of the detailed environmental studies.
The following mitigation types were found in the practice of designing linear infrastructures:
• big game bridges, amphibian, reptile and small mammal corridors (usually tunnel),
• wildlife protecting fence,
• relocation (transplantation or transfer) of protected species, and communities (see 7.2.).
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Game bridges
The greatest investments in the field of wildlife protection during road constructions are theones made for the interest of protecting big mammal species. By far the most prominent ofthem are the ones under construction along the railway line connecting Hungary to Slovenia,namely a 375 metres long tunnel and two viaducts of 1400 and 200 metres long. These invest-ments were necessary mainly for landscape protection interests. (Without these structures therailway line would require several hundreds of metres long and of some ten metres wide andtall railway beds.) Railway tunnel and viaduct are the best for nature conservation aspects(avoiding fragmentation) and at the same time they are the most expensive ones. Not surpris-ingly, no other structures of this great dimension were erected in the last 60 years.
A bridge over water courses or earth roads with at least 4 m wide bay serves as movement cor-ridor for several, even for big game species. Concerning the high costs of separate level gamebridges existing bridges are worth widening for a much lower budget. Main principles of de-signing game tunnels are listed here (valid also for bridge enlargements):
• Sizing of openings has to regard the empirical value (the so called “relative enclose”)deducted from the utilization studies of game bridges. The size of the opening is dependenton the length of the bridge and the size of the species: e.g. assuming a 34 m long bridge, thedimension of openings for roe deer would be about at least 25 m² (for example cca. 4×6m), for red deer and fallow deer about 51 m² (for example cca. 4×12 m) at minimum,
• The surface has to be slip-proof and possibly similar to the natural surfaces (avoidpattering),
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Figure 7.3.1. There were no roe deer victims since 1996 along the M1 motorway probably be-cause animals do use the game bridges.
• The inside walls of tunnels have to be painted dark up to 80 cm height and white above,
• Entrance are has to be supplied with vegetation cover and with noise and visibilityreducing palisades,
• Habituation of animals to use the bridge should be achieved through feeding and theexclusion of hunting in the area.
It is important to render impossible the usage of the crosses by man and vehicle (for tunnelsand bridges as well). Aspects of designing game bridges are as follows:
• The bridge structure serving as overhead bridge should be hour-glass shaped,
• Regarding dimensions, a minimum width is 8 metres for roe and wildboar and 12–35metres for red and fallow deers is suggested,
• Surface of overhead bridge has to be covered by 50 cm of soil, and vegetation,
• Vegetation composition should harmonize with the native surrounding type,
• Habituation of animals should be achieved as for underpasses.
The construction of tunnels and bridges is of no use if the road is not protected by wildlifefences. Required density of corridors depends on game abundance and population densitiesand on behavioural characters of animals living in the habitats affected. The placement of cor-ridors is to be defined together with authentic wildlife managers of the area.
Only two game bridges were constructed in Hungary, both along the sections of the M1Motorway (147+550 and 151+750). Both ends of corridors are cornet-shaped. The 20 metreswide concrete structure is covered by earth and vegetation (Figure 7.3.1.). Parallel with themotorway a 20 m long 140 cm high stumpwood fence leads the game animals to the fun-nel-like ends of corridors. These log fences hide the motorway (from animals) on one side andreduce noise on the other. The log fences are continuing on the top of the bridges on both sides.The total width of bridges (20 metres) are reduced to only 5–7 metres by the covering vegeta-
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Figure 7.3.2. Game bridge over M1 motorway
tion planted on the bridges. As a post-investment, the wildlife protecting fences at the bridges(in 150 metres long at all four sides) were covered by light-reflecting nets. Case study no. 7shows the results of an experimental study about the efficiency of the big game bridges.
Case study no. 7. GAME BRIDGES OF THE M1 MOTORWAY
By G. Takács and A. Pellinger
The aim of the study of two game bridges over the M1 motorway was to:
• assess the use of the bridges by game after the opening,
• to study the status of the bridges and connecting establishments.
The study area
The area under examination lies along the M1 motorway from Gyõr to Hegyeshalom(section 146 and 152 at Lébény). The motorway approaches the most protected areashere (North Hanság Territory of the Fertõ–Hanság National Park). In this road sectionseminatural vegetation of outstanding values (Fûzfa Islands and Vesszõs Forest) are tobe found close to the motorway.
Game population estimations show that among big game species the roe deer (Capreo-
lus capreolus), the deer (Cervus elaphus) and the wild-boar (Sus scrofa) occur here, inan estimated 2250 individual numbers altogether. An estimation of hare (Lepus euro-
paeus) population number based on the local hunting association was cca. 3000–3300.
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Figure 7.3.3. Game bridge over M1 motorway
Some game bird species are also listed in the game management inventories, as pheas-ant (Phasanius colchicus) and partridge (Perdix perdix) and the inventories mentionthe occurrence of the strictly protected great bustard (Otis tarda) as well.
The game bridges
Two establishments were constructed along the motorway exclusively for ensuring themovement of big game species across the road. Both ends of corridors are cor-net-shaped. The 20 metres wide ferro-concrete structure is covered by soil. Parallelwith the motorway (in only 20–30 meters long instead of the proposed and planned 100meters) a maximum of 140 cm (instead of the proposed 180 cm) high stumpwoodfence leads the game animals to the funnel-like ends of corridors. These log fenceshide the motorway (from animals) on one side and reduce noise on the other.
The 20 m width of the bridge will be reduced to 5–7 m by the time the planted vegeta-tion will reach mature size. Only shrub and tree species of the natural vegetation weresuggested to be planted, however, the planting was implemented by other – and in mostcases by alien – species. The most frequent species is pyracantha (Pyracantha cocci-
nea) which follows along the log fence. Instead of the native dogberry (Cornus
sanguinea), an ornamental shrub, the tatarian dogwood (Cornus alba sibirica) wasplanted. The common ash (Fraxinus excelsior) was planted to the funnel gates. Part oftrees and shrubs actually planted could not cope with the summer heat and totally driedout, another part of them was dug up by wild-boar.
The common wildlife protecting fence separates neighboring areas from the motorwaythat continues on the game bridges as well, beside the log fence. The height of the wire
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Figure 7.3.4. Game bridge over M1 motorway
fence varies with the game species expected to occur on the areas in concern: 260 cm ifdeer is characteristic for the area, and is only 150 cm if no deer is expected. The wirepattern is not uniform: verticular wires are 25 cm apart from each other while distanceof horizontal ones ranges from 8.3 to 25.4 cm. In the beginning of operation period thedrains were not correctly shunted by wirenet fences, consequently larger vertebratescould go on the road and the number of accidents increased in some places. This prob-lem was solved (by making fence detours at drains) in the first half of the year 1997.
Those culverts with 1 meter in diameter, the opening of which was sank to 20–25 cmbelow the ground level, primarily ensure passing the motorway for amphibians. How-ever, they frequently dry out during the summer drought. Other canals and tubes cross-ing the motorway below the ground level have wildlife protecting function as well.Their openings are to be found on the external side of the fence, thus they can serve themovement of some greater bodied species.
Results
Use of big game bridges and other wildlife protecting structures
The use of the bridges was detected since 1996.
The most frequent game tracks belong to roe deer and wild-boar. 60–70% of tracks arewild-boar tracks, 20–25% are roe deer tracks, the remaining 5–10% belong to deer, foxand other species. Unfortunately humans also started to use the game bridges even bycar.
Trends in run over statistics
Number of road kills since 1996 shows a significant decline (200 cases in spring 1996to 126 autumn 1998).
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Figure 7.3.5. Red deers often use game bridges
Hares are far the most frequent victims of accidents. Considering the number of cau-salities, foxes and cats are the second and third in the statistics. The number of harekills is continuously decreasing since 1996 (from 99 to 26 to the end of studied time pe-riod).
Pheasants and owls (little owl and long-eared owl) follow cats in statistics. Number ofkilled pheasants shows seasonal pattern. Number of runs over is usually about twice(10–15 cases) in the breeding season (first half of the year) than in the second half ofthe year (5–7 cases). Owl carcasses are usually rare (1–7 cases) along the studiedmotorway section except of 1997/1 (24 cases). Low-flying birds above motorways arein danger generally. Carcasses of formerly run animals attract buzzards and other –partly or exclusively – carrion-eating species. Number of cases increased (2 in 1996, 2in 1997, 4 in 1998).
Roe deer was run over 9 times in 1996, 8 times in 1997, and 3 times in 1998 on theGyõr–Hegyeshalom section of the motorway. The formerly high number of roe deersin accidents was the consequence of the insufficiently closed drains. After repairingfences in first half of 1997 the number of running over roe deers significantly de-creased. There were no roe deer victims since 1996, probably because animals do usethe bridges.
Running over wild-boars was frequent in 1996, but no case was reported from 1997and only one occurred in 1998.
Status of wildlife protecting establishments
The technical status of game bridges seems to be good, however, the planted vegeta-tion is not suitable. The species planted do not belong to the suggested tolerant speciesof the natural flora but mostly to ornamental species. Plantation was not carried outwith sufficient care, the soil layer was too shallow to keep moisture, even drought tol-erant species dried out. The plantation of following species is proposed: blackthorn(Prunus spinosa), wild rose (Rosa canina), field maple (Acer campestre).
Status of wildlife protecting wirenet fence is good on the studied. It is connected wellto the bridges and tunnels (ecological tunnel, channel etc.). Poplar was planted in sev-eral rows along the motorway, the selection of the native white poplar (Populus alba)instead of the cultivated canada poplar (Populus canadensis) could have been moresuccessful. The invasion of shrubs started with common alder (Alnus glutinosa), wil-low (Salix cinerea), black haw (Viburnum opulus). Game footprints, primarily wild-boar and roe-deer tracks are abundant in the close vicinity of the north side of the road.
Summary
The utilization of the established two game bridges – primarily by roe deer andwild-boar – was proved despite the insufficient vegetation. The status of wildlife pro-tecting fence is good in general. However, vehicles do run over animals on the motor-way. Victims are mainly smaller bodied mammals and birds.
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Wildlife protecting fences
The function of wildlife protecting fences is two-fold: it protects man and wildlife at the sametime. There is no effective standard or technical guideline for its sizing. Experiences of closedbig game husbandry show that the effective fence in habitats of fallow and red deers is260–280 cm high (optical height). In areas with other big game species (roe, wildboar,moufflon) the 160 cm height of fences is enough.
Two types of wildlife protecting fences were used along the Hungarian motorways until now.The net size of the one named SALGO-FENCE is as follows: vertical wires are 152 mm apartfrom each other, while distance of horizontal wires gradually increase from 83 to 254 mm(bottom to top). CYCLONE wildlife protecting fence was used along the M5 Motorway.There are several types of this product, among them those densely wired fences of which hori-zontal wires are 89 mm apart from each other until ten units high. The total height of the verydense net ensures the protection of small invertebrates as well.
Experiences from other motorways show that at culvert openings the fence is usually incor-rectly fitted to the surface and vertebrate species do cross it. A solution can be the fitting of op-tical game alarm cables along ditches together with hanging loads (length of 20–30 cm) atevery 5 cm and the fence has to be jointed to the concrete abutment of the culvert. This solutionallows animals to use the culvert as subway.
Another solution is to continue the fence down to the bottom of the ditch. Special attention hasto be paid in this case for regular cleaning of the fence during maintenance. Fixing the fenceinto the ground (to a 30–40 cm depth) protects against digging up (by wild-boar, fox or straydog) and at the same time increases stability.
Fence posts are usually made of 15 cm thick preserved black locust posts. The distance ofposts is usually 3 m or less. In the case of a fence of 2.80 m height the post-length should be4.20 m 1.20 m of which will be in the ground. Side-supported posts have to be placed in every30–50 m. Expected durability of a well maintained fence is 10–15 years.
In semi-natural habitats rich in vertebrate species a dense net (of about 1 cm cells) type ofwildlife fence should be applied to avoid kills of small-mammals.
Amphibian and reptile passes – technical aspects
In the Hungarian road design practice amphibian and reptile passes (tunnels) are most fre-quently made of circular tubes of 1 or 1.2 m diameter (ROCLA RAP or TUBOSIDER types).The two ends are surrounded by concrete wall or stonewall. If the bridge is made of water per-meable material than its bottom surface should be covered by waterproof concrete. Lightshafts have to be made in the central safety zone separating the different courses of the motor-way (see Figure 7.3.2.). The light shafts should have 1.20 × 1.20 m or 1.40 × 1.40 m inside dia-meter, and their inside surface should be covered by dense white tixotrop layer reflecting thelight down to the tunnel. The length of tunnel depends on the total width of the road, usually35.70–37.80 m. Light shafts have to be covered by a screen for safety reasons.
Animals have to be driven towards the passes. NETLON H10 net is used for this purposealong the M3 Motorway (0.55m tall, wire distribution is 6×8cm, see Figure 7.3.3). The fence isworth digging 10 cm deep into the ground for increasing stability and barrier safety. Fenceposts can be 10 cm � black locust posts or L 50×50×5 mm steel nailrod posts. Their distance isbetween 2–2.4 m, depending on ground features. A plastic-covered bracing wire increasesfence stability. The optical game alarm cables (see also wildlife protecting fences) are worthusing for bracing as well.
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A 5 cm wide upper border, leaning to outward side (45°) can avoid climbing animals fromroad.
L-shaped concrete walls can also drive frogs to the tunnels (wall height should be 0.5 m).Aqueducts and small current crosses can also serve as special reptile and amphibian passesalong motorways.
Case study no. 8. METHODS OF PLANNING AND BUILDING FROG-TUNNELS,BASED ON EXPERIENCE ALONG THE LAKE FERTÕ
By A. Pellinger and G. Takács
Introduction, problems
The case study demonstrates the conflict between roads and animals within the terri-tory of a National Park (Fertõ–Hanság).
Road No 8518 that connects towns near Lake Fertõ with Sopron, has been decimatingthe amphibian populations of the region since the beginning of the 1980s when trafficincreased significantly. Every autumn and spring since 1987, volunteers have built res-cue systems on the most crucial road section, between the towns Fertõboz andHidegség. The experience of this 13 years long rescue project is presented below.
Location
Lake Fertõ is the westernmost steppe lake in Europe, situated at the border of thesteppe-woodland zone characteristic to the Carpathian Basin. During the past 200years two-thirds of the lake became covered by reed. In the littoral zone salt grasslandsand wet meadows with seasonal puddles are found. Hundreds of thousands of amphibi-
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Figure 7.3.6. Tunnel for amphibians and reptiles under the M3 motorway.
ans migrate every autumn to overwinter in the hills along the lake, while in spring mi-gration takes place just to the opposite direction. The road around the lake dissects thismigration route. Although the littoral zone of the lake is accompanied by woodlands atseveral places, migration is most intensive on the one km section between Fertõbozand Hidegség. The distance between the littoral zone and the mixed woodlands – ses-sile oak (Quercus petraea) with Turkey oak (Quercus cerris), black walnut (Juglans
nigra), and black locust (Robinia pseudoacacia) – of the nearby hills is only 300metres here. The area of the National Park is a Biosphere Reserve, and in part protectedby the Ramsar Convention.
The driving – saving system
The migration of amphibians, outstandingly intensive both at the country and Euro-pean level, has been observed since the 1970s. With the increase of traffic from the1980s on, the rate of road kills increased parallel.
In 1987, based on experience in Germany, the Forest Protection Department of theUniversity of Forestry in Sopron, the “Kaán Károly” Ecoclub of the University of For-estry, and the Sopron Group of the MME/BirdLife Hungary started building a cheapdriving – saving system to moderate or cease the mass destruction. The project wassupported by several volunteers, schools and nature protection organisations. In 1993aqueducts, serving as frog-tunnels have been built.
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Figure 7.3.7. Amphibian tunnel under the M3 motorway.
The method applied was the following: in spring and autumn volunteers built a nylondriving-fence of 80 cm height streched on sticks, fixed in the ground 5 cm deep, alongthe lake-side of the road. The fence stopped the animals from moving onto the roadsurface and drove them into plastic buckets previously sunk into the ground. These“traps” had to be emptied several times a day and the animals carried by manpower tothe other side of the road. Two industrial roads – one from the south, the other from thenorth – joins the affected road section. As the driving-fence had to be interrupted atthese places, the prevention of destruction could not be complete.
To further develop the method, the nylon fences were connected to the two tubular aq-ueducts 60 cm in diameter, lying 300 m apart at the given road section. Although theanimals were found to have used both aqueducts, the use of buckets could not be elimi-nated because of the large distance.
With the above system destruction could be significantly moderated. However, it wasnot as effective as expected owing to the vulnerability of the fence and the great man-power need of the method. In 1991, the Fertõ–Hanság National Park came to existenceand took over the organisation of the frog saving project. Based on earlier experience,the National Park Headquarters initiated the building of a permanent driving – savingsystem that would solve the above problems and could ensure a safe bridge to the otherside of the road. Depending on financial conditions, the system would involve specialaqueducts built 50–100 m apart under the road surface, and permanent driving-fencesattached to them.
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Figure 7.3.8. Frog-leading wall made of concrete by the M3 motorway.
Results
The special aqueducts (frog-tunnels) built from 1993 can provide crossing routes forthe animals not only in the migrating season, but throughout the whole year. The fivefrog-tunnels built until 1998, together with the two old aqueducts, could handle themost crucial 1000-metre section. The connecting permanent driving-fence, however,has still not been built owing to financial problems.
The special aqueducts built for migrating animals are equipped with light-shafts. Sinceno significant difference has been observed in the use of traditional aqueducts andfrog-tunnels, light-shafts may as well be discarded.
Summary
Migrating amphibians had been run down in enormous numbers in autumn and springat one section of the road along Lake Fertõ. The frog rescue project initiated by NGOswas one of the most effective spontaneous nature conservation actions in Hungary.However, it was not effective enough in the long run. The Fertõ–Hanság National Parkhas started building permanent driving-fences and frog-tunnels. This solution, thoughexpensive and not yet fully accomplished, proved to be highly effective.
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Figure 7.3.9. Green toads are often killed on roads.
Transferring/transplanting populations of protected species
There are some examples of transplanting protected species in Hungary, mainly by transfer-ring them from mining areas or from areas devastated by water regulation or karstic water ta-ble reduction. An example for the second type of habitat destruction is the Tapolca Basinwhere a fen meadow had dried out and the last individuals of a strictly protected relictprimrose (Primula farinosa) had been unsuccessfully transplanted to several places. Theprimrose transferred to the Ócsa fen had flowered for 1–2 years after transplantation but latersimply disappeared. Few years after the unsuccessful transplantation efforts a small popula-tion was found in an adjacent basin to the original site. This population was also threatened byimmediate drainage. By retaining water on the habitat and by habitat reconstruction the spe-cies was preserved.
Ferns (Dryopteris cristata) were transplanted in another experiment from its damaged habitatto the Dabas fenwood. However, individuals survived for about 10 years, they did not repro-duce any more and finally died. The strictly protected Hungarian colchicum (Colchicum
hungaricum) was transplanted in vain as well from its habitat that is to disappear due tomining. There are rare examples of successful relocations of plants, as of the protected sandiris (Iris arenaria). Only few stems were planted to a sandy grass at Ócsa and now it grows insurprisingly great numbers.
Translocating animals is less easy than that of plants, and in the case of invertebrates it is al-most impossible. However, there are exceptionally simple relocations of animals, as for exam-ple creating a new sand wall for the protected bee-eaters (Merops apiaster) not far from itsformer breeding habitat to be mined. Translocation of the European souslik (Citellus citellus
syn. Spermophilus citellus) from an airport at Pécs to some suitable places of the country waspartially successful as well.
7. 4. OVERVIEW OF COMPENSATION MEASURES
Compensation – according to the sense – is the replacement of a damaged or lost habitat at an-other site where we attempt the reconstruction of the original natural values and functions(Török 1995). Successful compensation measures within Hungarian conditions can be ex-pected for grassland (e.g. meadow-type) or for wetland habitats. Establishing a forest of nativespecies and with a wide age distribution needs about 60–100 years and consequently realisingenvironmental compensation in this field is irrelevant within our circumstances.
Planting vegetation
Planting vegetation along roads may have three objectives:
• landscape protection purposes and landscape amenity value,
• taxon specific protection purposes (to avoid cross flying of birds etc.),
• environmental protection purposes (pollution, erosion control).
Basic requirement is to consider safety aspects, namely that plants will:
• not cover traffic signs,
• not hinder road maintenance,
• optically support driving.
Positive aesthetical function of roadside plantations (of trees, shrubberies, mixed plots) can beensured by careful planning which regards the neighbouring landscape as well (Török 1995).
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Requirements of harmonic plantations
• Avoid regular, unified tree-line planting which would increase monotony,
• Adapt vegetation to the relief and landscape and plant in groups like groves,
• Older and valuable elements of vegetation are worth preserving and reconstructing(regenerating),
• Forest surfaces opened up should be closed as soon as possible,
• Apply plants of diverse appearance and of different ornamentical effect,
• A rolling surface can be well integrated with dwarf shrubs,
• Use tree groups to optically dissolve sharp and mechanical surfaces for example atoverpasses,
• It is important to analyse landscape colours and to integrate them to the vegetation plans.
Consider convex and concave horizons, i.e. on outstanding areas for example at top of slopesand on embankments use low species, but do not use them in valleys or depressions.
Planting tree lines and shrubs
Tree-lines and shrubs should provide the following services:
• protect neighbouring habitats from adverse effects of traffic (noise, dust, emissions, light,motion),
• eliminate erosion effects,
• function as wind and snow barriers,
• create new habitats,
• increase flying height of birds,
• raise amenity value of the landscape thus exerting positive psychological effects ondrivers.
The following aspects deserve attention during planting:
• type of the wider environment (outskirts, through sections in settlements etc.),
• exposure of road to poles,
• slope and cutting characteristics,
• microregion type,
• forecasted traffic intensity,
• soil types,
• water regime and water management of soils,
• prevailing wind direction,
• other selection aspects of species and varieties to be used (see below).
Only standard materials can be used for plantation. Tree planting is allowed in a distance of 3metres or more from the road. Vehicles leaving wind protected settlements, structures or cut-
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tings are in danger of sudden wind-pressure. Dangerous wind-pressure can be decreased byplanting gradually thinner and thinner vegetation at well defined places. Regulations andsafety measures have to be strictly followed during planting.
Guidelines for selecting species
Species recommended to plant in road verges or tree rows should have the following charac-ter:
• native or species of the native associations of the given microregion,
• ecological requirements fit to the environmental conditions of the roadside (soil, precipi-tation, exposure, elevation),
• high contamination and pollution tolerance,
• ability to cope with extensity, drought, and lacking care,
• important aesthetical value,
• rapid growth rate,
• appropriateness to the given landscape,
• possibly long life-span,
• host plants of pests excluded (Acer negundo, Morus spp.),
• no fruit trees, or invasive and aggressive weeds,
• market availability,
• easy propagation,
• low risk of injury in case of accidents (e.g. no thorns),
• no disturbance of traffic (by visual effect, monotony, cover, mass propagula, seeds on roadsurface).
Special aspects to be considered:
• tree species with suitable stem height for tree-lines,
• dense canopy species for aerodynamical protection,
• avoiding weak and fragile branch species in areas of wind and snow protection,
• colonizing species for slopes,
• species with special demands for the separation closures (tolerant to drought, salt, light,hot and dressing),
• drought tolerant species to dry sites,
• humidity tolerant species to wet sites,
• salt tolerant species to alkaline sites,
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• species tolerating high water table level for lake and river banks,
• species sprouting fastly are advantageous (Avena, Bromus).
7.5. MAINTENANCE ASPECTS
6/1998 (March) Decree of the Ministry for Transport, Communications and Water Manage-ment regulates the maintenance of roads and their inherent structures.
Technical managers of roads have to ensure the conditions of safe and continuous traffic andthey are obliged to maintain all offices, places, stocks, deposits, maintenance and social estab-lishments necessary to fulfil these tasks. Road management tasks are described in the NationalRoad Management Rules (OKKSZ) effective for the total country area. The regularity and thelevel of the operation and management tasks of a road depend on the service level classes de-fined in the National Road Management Rules.
Road maintenance tasks:
• winter defrost,
• maintaining vegetation (chemical herbicides, plant protection, pruning),
• cleaning of road pavement and engineering structures,
• restoring pavement as necessary,
• maintaining road shoulders and water drainage system,
• changing or replacing pavement signs and signals.
During the execution of these road maintenance tasks the environmental aspects should al-ways be considered by:
• fulfilling technological guidelines,
• using materials dangerous to environment economically, within reasonable limits,
• development of operation and maintenance technologies.
One of the most fiercely discussed road maintenance activity is the winter anti-freezing andice clearing. Snowy pavement and frosty pavement both resulting in a slippery road surfacewith high accident risk can be prevented or resolved by cleaning, by roughing or by spreadingmelting agents (de-icing salts or chemicals). The most widely used melting agent is the com-mon salt (NaCl) and its solution. Salt adversely affects cars, pavement, engineering structuresand natural environment.
Aspects of maintaining vegetation in public domain
• pest control is described in a special regulation about plant protection,
• arboreous vegetation (shrubs, tree-line, forest belt) should be maintained as ordered byspecial authorities,
• grass mowing should be regular and time intervals depend on service level (4 to 1 times ayear),
• vegetation with protecting function but out of the territory of road management has to bemaintained by the owner.
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7.6. EVALUATION AND MONITORING OF THE EFFECTIVITY OF MEASURES
Monitoring systems along the Hungarian road network
There were 32 monitoring sites along the national road network for monitoring the pollu-tion effect of transportation. Monitoring carried out at these sites is in most cases based on ar-bitrary decisions, no standard protocol exists so far. In most cases, pollution monitoring iscarried out, the first example of an integrated approach was along the M0 expressway, whereenvironmental status surveys were accomplished before and during construction and a year af-ter its opening (case study no. 1).
The level of environment pollution and its dependency on traffic intensity can be well moni-
tored by the above studies. Monitoring sites with different traffic level were determined alongthe roads of national importance (motorways, main roads). Monitoring activities at these sitesprimarily aims to follow the quality changes of soil, water and vegetation.
Wildlife (nature) monitoring systems of all the motorway sections constructed and opened inthe past one and half decades have not, or have only partially fulfilled the professional require-ments of monitoring studies. The longest data collection interval was not longer than fiveyears. Even the focus of studies were questionable concerning base requirements of biologicalindication. Trends in supraindividual systems affected by a newly opened road should be thesubject (indicandum) of a monitoring activity, as for example changes in vegetation structure,trends in breeding bird communities, alteration of amphibian or large game population sizes orbehaviours. Analysing consecutive bird occurrence lists of one or two years can not be consid-ered as a real monitoring (the monitoring budget of some hundred thousand HUFs a year usu-ally allows only such a study scope). Consequently, these ornithological checklists cannotfulfill the requirements of an environmental study.
All, all the expected effects on nature of a planned road section have to be defined accuratelyin the preparatory licensing phase of road design within the detailed EIA. Aims, objects andindicators of biomonitoring have to be defined on the base of the expected environmental ef-fects. (Indicators are those organizations which clearly detect and reflect – by their occur-rence/lack, change in population size, in distribution or in other behavioural variable – anenvironmental factor or the status change of an environmental factor.) The Hungarian design-ing practice routinely requires (or compiles) the detailed plan of the necessary nature monitor-ing studies as early in the planning processes as possible (during the licensing phase).Certainly the content of the monitoring plan should be harmonized with and accepted by therelevant nature conservation authority. The results have to be accessible by relevant natureconservation authority as well as by designers. Today the results are not public. Time intervalof nature monitoring should be set to a minimum of 10 years.
7.7. SUMMARY
A great number of environmental establishments were constructed along the Hungarian roadnetwork especially in the last 15 years financed from about 5–10% of the total constructionbudget. About one tenth of the environment protecting means (culverts, noise reducing wallsetc.) are wildlife protecting structures. There are no guidelines for planning nature conserva-tion measures, the efficiency of the realised protection measures are seldom followed up bywildlife monitoring programmes.
Among nature conservation measures, the ones protecting game (fences, passes) are the great-est investments in volume and in numbers as well. An obligatory part of concessioned motor-ways is the wildlife fence. However, nobody studied yet the habitat fragmentation effect of
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fences (made for safety purposes at first instance) in details. The segregating effect of fenceson game populations cannot be neglected. Thus steps should be made toward a more extendeduse of other measures decreasing collision risk (light reflecting prisms, odours).
Only the big game bridges of the M1 Motorway were studied during operation. Monitoringstatus and efficiency of big game passes is of prime importance for nature conservation (be-cause these establishments decrease the fragmentation effect of linear infrastructures) and forthe designers (for the purpose of planning cost-efficient establishments) as well.
Concerning amphibian, reptile and small mammal passes the experience gathered is more thanenough in Hungary. However, compiling a suitable planning guideline is the task of the nearfuture.
An everyday task of investors is vegetation planting (and sometimes the translocation of spe-cies) thus there is an urgent need for reviewing the methodology at a national scale and for aplanning guideline accepted also by the nature conservation sector.
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Chapter 8. Habitat fragmentation and future infrastructure
development
8.1. INTRODUCTION
There is a continuous increase of mobility demands in Europe and in all developed countriesof the world. The effective operation of the united European market strongly depends on un-hampered, fast, safe and economical transport of passengers and goods. This huge mobilitydemand is satisfied mainly by road transport, 90% of all passenger transports and 70% offreight transports are directed to roads.
Conforming all above the establishment of a Pan-European road network deserves high prior-ity. The founding document of the European Union – enacted in 1993 – provides the opportu-nity of supporting and promoting the development of road network out of the Union as well.
The Parliament Decree no. 68/1996. (9. July) defines the main trends of the Hungarian trans-portation policy as follows:
• to promote the integration to the European Union,
• to improve the conditions of co-operation with the neighbouring countries,
• to promote the well balanced regional development of the country,
• to preserve human life and environment,
• to operate traffic and transportation effectively and in conform with the market.
The transportation policy of Hungary mentions the European integration at first place not bychance. Transportation – and especially the development of motorway network and its links tothe European network – will prospectively be a topic of outstanding importance during theacquisition negotiations.
It is of high importance to represent the mature and approved (by the Government and by theParliament) long-term policy plan defined by legislatory means during negotiations. The“Long-term development plan of the Hungarian motorway-expressway network” should beapproved as law within the frame of the Regional Policy Plan of Hungary (OTT) under prepa-ration. Both the OTT and the motorway-expressway network development plan have to servebasically a more equalized regional development of the country and would consider the possi-bilities of strengthening the social and economical relations with the neighbouring countriesby joining the international motorway-expressway network.
The long-term development plan of motorway-expressway network is under conciliatory ne-gotiations with the neighbouring countries at ministerial level. Integration of actual tasks withRomania, the Slovak Republic and Slovenia has already been initiated.
The most important public road network development task regarding the promotion of the EUacquisition is the acceleration of motorway-expressway network construction. Five of thePan-European transport corridors cross Hungary and their development priority is set by theGovernment Decrees no. 2119/1997. (14. May) and 1085/1997. (24. July).
The aim of the motorway-expressway network plan of Hungary is to define the necessary con-necting corridors between regions and settlements in medium-term (until 2008) and inlong-term, i.e. until the total motorization (2030 expectably) and moreover to codify the plan.
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The importance of connections instead of layout (route) definitions has to be stressed. Accu-rate layout selection and elaboration of feasibility conditions (financing schemes) do not be-long to the long-term planning. The codifying process has to insist on approving the con-nections for the interest of making the medium-term and long-term plans of motorway and ex-pressway networks, and to disseminate the plan for the domestic and foreign inquirers and po-tential investors.
8.2. POLICIES AND STRATEGIES/TRENDS
Network development strategy
The objectives of a motorway-expressway network development can be drafted as follows:
• to promote the international and inland network connections and to satisfy transportationdemands,
• to improve the road conditions (decreasing accident risk, travelling time and transpor-tation operation costs) for the interest of relieving spatial inequalities of the country byrendering a harmonic regional development policy possible,
• to reduce the adverse environmental and natural effects of transportation,
• to increase transportation efficiency.
Recommended construction standard
The proposed elements of the motorway-expressway network development plan are motor-way sections of 2×2 and 2×3 traffic lanes and expressway sections of 2×2 traffic lanes.
Principal difference between motorway and expressway is their different service level. Ex-pressway is usually designed for lower speed and less traffic lanes, separation strips and shoul-ders can be narrower. As the plan recommends, the development of the expressway networkcan partially utilise certain elements of the existing principal road network, namely by widen-ing them (up to 2×2 lanes). This recommendation is not only economical but environmentallybeneficial as well because it does not require as much natural area for the transportation corri-dor than designing a new route. At the same time, the suitable development of the connectingsecondary road network will have to support the traffic of slow-running vehicles and machin-ery excluded from the former main roads transformed to expressways.
The draft plan recommends motorway for all important international corridors and for areaswhere the intensive inland traffic deserves it. Important international corridors are the traces ofM1, M15, M3, M30, M4, M43, M5, M7 and M70 motorways with intensive traffic already atpresent, as well as the corridors Tornyosnémeti – Miskolc – Debrecen – Ártánd (M30, M3,M35, M40, M47, M4), Budapest – Szekszárd – Illocska (M6, M56) and Füzesabony –Szolnok – Kecskemét – Dunaújváros – Székesfehérvár – Veszprém (M8) the importance ofwhich depend on requirements of international agreements and on capacity demands. For thepurpose of relieving the M7 Motorway at the Lake Balaton an alternative trace for the Helsinki5th corridor was designed along the Letenye – Kaposvár – Dombóvár – Dunaújváros –Kecskemét – Szolnok – Füzesabony (the existing M61, M8 roads) direction. The proposedlayout relieving the 4th primary road follows a new route and offers expressway level, mean-while does not exclude the possibility of further development of the road to a motorway de-pending on traffic development. Moreover, motorway level is offered for the final construc-tion of the M0 expressway (Budapest). The draft motorway construction standard proposes
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2×2 lanes except for certain sections of the M0 expressway and for the Budapest – Sza-badbattyán section of the M7 Motorway, all requiring 2×3 lanes in the distant future.
Networks investigated
The studied roads of a sum 30.000 km length represent the national public road network andcan be considered as the basic network. The existing motorway-expressway network, the pri-mary and secondary road systems and those parts of their connecting inferior road networkswhich have significant corridor function are all included in the study.
Only those new motorway-expressway elements of the planned network have already beenplanned in details which will be established in the near future. Although designers attemptedto plan routes as precisely as they could, these routes should be considered “corridors” onlybecause a trace is effective and determined only if all necessary licensing plan phases and pro-cedures are successfully implemented and a valid building permit is received.
After the full establishment of the motorway-expressway network the service level will be asfollows:
• all corridors belong to international road network are motorways or expressways,
• most important road connections to the neighbouring countries will be of motorway-level,
• all counties and county-seats will have connection to the motorway-expressway-network,the network will improve the connections between county-seats,
• travelling time between the capital and the counties, county-seats will be shorter.
Planned developments
The development plan recommends two phases for establishing the motorway-expresswaynetwork:
• in medium-term until the year 2008, and in (Figure 8.2.1) long-term until the year 2030.(Figure 8.2.2.)
The medium-term development proposal of the motorway-expressway network recommendsthe accelerated realisation of planned motorways and expressway-transformations to motor-ways both supporting the economic policy and the European integrational interests of Hun-gary.
Road density of Hungary (both of national and of local roads) is similar to the road density ofthe EU countries (however, service level is less developed). The most important difference isthe lacking motorway-expressway network. This is reflected by the motorway-expresswaydensity data of 4.5 km for 1000 km², which is extremely low if we consider the correspondingdata of for example the two small countries of the EU. The motorway-expressway density ismore than 50 km for 1000 km² in Belgium and in The Netherlands.
In relation to EU integration, the most important parts of road network development are theones supporting international relations.
Total length of the accepted Helsinki corridors’ sections to be constructed by Hungary is al-most 750 km. Government Decrees (no. 2119/1997, no. 2117/1999, no. 1037/2000) orderedthe construction of about 51% of this network (460 km) until 2008 (Figure 8.2.1.). This part ofthe network can be considered as medium-term phase of the motorway-expressway networkdevelopment plan.
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The draft long-term motorway-expressway network development plan was elaborated for theinterval until about 2030, by that time the forecasted level of motorization will be 430cars/1000 inhabitants. The motorway-expressway network after accomplishing the long-range development plan will be about 3470 km long about 2240 km of which will belong tomotorways and about 1230 km to expressways (based on the recent traffic intensity apprais-als).
Among expressways, several sections (with a total length of 470 km) will be developed gradu-ally from existing elements of the road network. The construction of about 770 km long newexpressways (with 2×2 traffic lanes) is expected.
Key routes of European integration
Road transportation has outstanding role in the field of passenger and goods transport of theEuropean Union as well. The establishment of the express railway network and the develop-ment of the combined transportation will presumably not withdraw so much transport volumefrom the roads that would significantly alter the present ratios and trends.
Inland corridors important for the Union (labelled with “E”) are practically of motorway levelor efforts are shown to develop them to motorways.
Regarding EU integration, the most important parts of road network development are the onessupporting international relations (Figure 8.2.2.).
A Pan-European initiative was launched for integrating the transportation policy of Westernand Eastern Europe. Its main aim was to develop an effective Pan-European transportationnetwork (including public road transport and motorway network). Participants of the confer-ence held in Crete in 1994 designated the transport corridors important for the EU and support-ing the development of the countries at the eastern border of the EU. These corridors wereamended in the Third Pan-European Transportation Conference at Helsinki, 1997 (23–25June). The approved transportation corridors of Hungarian importance are demonstrated inFigure 8.2.3.
The roads that coincide with these corridors are the most important ones concerning EU inte-gration and international motorway traffic connections. The following motorways (also listedin the draft Hungarian Motorway-Expressway Network Development Plan) fit to the Euro-pean corridors in Hungary:
• 4th Helsinki corridor: M1, M15, M1, M5, M43 motorways, Bratislava/Wien – Budapest –Constance/Saloniki
• 5th Helsinki corridor: M70, M7, M0, M3 as well as M70, M7, M61, M8, M3 motorways,Triest/Koper – Ljubljana – Budapest – Ungvár
• 5/B Helsinki corridor: M7 motorway, Fiume – Zagrab – Budapest
• 5/C Helsinki corridor: M6, M56 motorways, Plocse – Sarajevo – Eszék – Budapest
• 10/A Helsinki corridor: M5 motorway, Belgrad – Novi Sad – Budapest.
These are the motorway connections of Hungary requested from the neighbouring countrieson one side. On the other side they are inherent parts of the Pan-European motorway networkbasically important for the economic cooperation and trade relations between the memberstates of the Union and their neighbours.
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COST 341
105
Chapter 8
Sajó
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8.3. INDICATORS AND INDEXES OF FRAGMENTATION
Habitat fragmentation is the dissection of habitats (ensure the survival of living creatures).Habitat fragmentation by roads decreases physical size and dissects a given habitat patch atfirst instance. Several possible indicators can be found, and those meeting the following re-quirements may be used in various studies and monitoring tasks:
• are theoretically well-founded,
• have numerical value which easen comparison,
• well describe the degree of fragmentation for a given species group.
Theoretically the value of fragmentation is the difference between the average habitat
patch size of a given species or species group in natural (semi-natural) circumstances
and in disturbed environment.
However, the calculation or definition of this value face several methodical difficulties. Thefirst problem is choosing the basic status (time) because of the restricted data of past status sur-veys. Owing to this the indicator used for habitat fragmentation can be:
• the extension change of a known or presumed habitat, or,
• the change in population number; while,
• the number of run over animals can be a special indicator.
Numeric values regarding factors causing habitat fragmentation are:
• road density,
• traffic intensity.
The digitized spatial information model, elaborated within this project describes fragmenta-tion effect twofold:
• by the decrease of the average habitat patch size, where the main factor was the patchnumber increment,
• by calculating the area/contour ratio which showed the average patch character in everyroad type crossing the various habitats.
8.4. SUMMARY EVALUATION
Regarding habitat fragmentation some statements about the Hungarian motorway-expresswaydevelopment maps (see Figures 8.2.1. and 8.2.2.) have to be made regarding landscape and na-ture protection.
Hungary undertook to establish the “Helsinki corridors” thus the network development is un-avoidable. This development will cause further landscape fragmentation. Consequently if theRegional Policy Plan of Hungary (OTT) will be accepted officially than this will be the legalbase for dismembering (fragmenting) the macroregions of Hungary. The National Authorityfor Nature Conservation of the Ministry for Environment is the authority for preserving natu-ral areas besides protected areas and consequently will take part in the decision making pro-cess of the plan above.
Analysing the route directions in details without aiming completeness, the following opinionsevolved.
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COST 341
It is entirely unacceptable from landscape and nature conservation aspects:
• the realisation of the M0 expressway at the Buda section,
• the Barabás section of the M3 Motorway from the point of view of protecting the Bereglandscape as a unit,
• the M9 expressway section at the vicinity of Õrjeges.
Other route options surely affect areas that deserve careful treatment for the sake of preservingbiodiversity but no exact information was accessible about these varieties (for example in theBakony region, at the Õrség offset, the Vend region, the Hernád valley and others).
If the Government approves the network development policy in its present form and with theexisting draft corridor direction, than the nature conservation aspects of selecting the best lay-out within the planning corridor (described in chapter 7.2.) have to be followed as far as possi-ble. Wise selection of the best layout will bypass valuable habitats and will prefers arablelands and intensively cultivated grasslands (less valuable from the point of view of nature con-servation). To ensure the safety of water regime and related protected associations the best lay-out is the one that follows the highest reliefs. For the sake of landscape protection a layout thatfollows land-use type boundaries will be the best choice.
Forecasting the effects of the drafted long-term transportation network is impossible by ourknowledge. The potential of forecasting habitat fragmentation effect will be raised by themonitoring results of susceptible habitats.
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Chapter 8
Chapter 9. Economic aspects – rentability of investment, prices,
cost-benefit calculations, finance
All structures and measures belonging to a new linear infrastructure have to be financed by theinvestor (among them the ones required for protecting environment). Costs of establishing theenvironmental protecting structures form a part of the investment budget. During the inaugu-ration process, all authorities control the realisation/existence of the formerly approved struc-tures. Authorities are entitled to control the construction and to assure technical supervision atthe investors expense. Costs of research and development emerging during planning are alsoto be paid by the investor.
Investor orders a feasibility study in a certain phase of the planning – usually before the licenseplan or around that. Cost-benefit calculations are important part of these studies. The source ofcalculations are the expected investment costs including costs of environmental measures, ve-hicle operating costs, time costs, accident costs, as well as management and operation costsper unit. Afterwards the experts calculate the cost/benefit ratio, the internal return cost, the im-mediate efficiency and the time of return.
Beyond cost/benefit calculations and indexes (necessary for financing) there are other benefitsof realising an infrastructure establishment that are hardly or indirectly provable and are onlypartially or impliedly covered in the above feasibility studies. For example, if an establishmentrelieves living areas, substitutes cross-town links or decreases accident risk, than the establish-ment has significant environmental benefits even if the costs of the extended environmentalprotecting measures are considered.
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Chapter 9
Chapter 10. Summary
Status of Hungary concerning infrastructure and natural state greatly differs from that of theWestern European average. Service level of transportation network is much lower and at thesame time the total coverage of natural or semi-natural habitats are significantly greater (aboutone fifth of the country area). An addition to these is the favourable natural conditions of thecountry (Continental and “mediterran-like”) originating from its transtional climatic situationwhich results in a mosaic of diverse habitat types. In accordance with the consequently highbiodiversity, the status of nature conservation policy is well-developed. However, not all areasworth for protection are designated, 9.1% of the total area of Hungary is protected, which isclose to the desirable 12% (area of the nine national parks is 440.839 ha, area of the 38 pro-tected landscapes is 349.242 ha, and the 140 nature conservation areas have 25.793 hectaresprotected). Species listed in the Hungarian Red Data Book and protected species lists are pro-fessionally relevant. The law of nature conservation reflects the relative values of nature aswell, since it belongs to the strong laws in an European context.
Very few specialised studies about habitat fragmentation were carried out in Hungary untilnow, the present COST project has driven attention to this topic. We have to stress that scien-tific knowledge and competent experts are to be found in Hungary practically at the same levelthan in western Europe. Our challenge of wisely developing the infrastructure while preserv-ing natural values as far as possible, is extended moreover by the COST 341 project. Hope-fully all designers and decision makers will know that botanical, zoological and ecologicalknowledge have principal role in planning if we want to preserve nature. Nature can be pro-tected in situ, exclusively on its own habitat. The principle of sustainable development has tobe applied while developing infrastructure. It can be stated, that the preservation of natural
values can be obtained primarily by choosing the best layout for linear infrastructures.
In the present report the structure and basic data of linear infrastructures together with their ef-fects on nature were discussed. The habitat fragmentation effect of linear infrastructures de-served special emphasis. The characteristic feature of transportation networks affecting thespatial structure of Hungary is the heavily centralised and the radiating design. Common coun-try level feature of both the road and the railroad transportation is the lack of transversal con-necting elements, namely the corridors (of suitable capacity) between eastern and westernregions which – at the same time – would relieve Budapest and its Danube bridges. This fea-ture results in the overburden of roads going to and from Budapest on one side and in the lowlevel of cooperation between the two parts of the country separated by the Danube.
Relatively few researches dealt with habitat fragmentation effects of linear infrastructures –among them of roads – in Hungary. Their results, however, show significant difference be-tween roads depending on their size and traffic intensity. The effects of narrow (paved) roadswith little traffic is insignificant if compared with motorways or expressways the fragmenta-tion effect of which is really strong. Even wider roads, do not alter the vegetation further fromthe road but do hinder propagula spreading. This effect leads to a poorer vegetation in thelong-run. Habitat fragmentation effect of roads seems to be more important in the context ofinvasive weed species and other disturbance tolerant species which all utilise roads for spread-ing fastly to new habitats.
Environmental effects are more complex in the case of animals. Contrary to the expectations,no significant lead accumulation was found rarely in animals (and plants) living along roads.However, segregation is well demonstrated in certain animal groups (mainly in amphibians)
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Chapter 10
where the number of animals in collision is so high that it surely affects population dynamicsand demography. Fenced motorways similarly segregate big game populations. We have lessknowledge about insects, but the fact that wider roads distract several insects (even if they flywell) is well known and thus roads hamper the movement of these species.
Comparing to Western Europe, only few establishments (frog tunnels, game bridges) weremade for supporting animals crossing roads. The study of animal passes showed that animalsmainly do use them and that certain modifications are necessary in their design in the future.
A great number of environmental establishments were constructed along the Hungarian roadnetwork especially in the last 15 years. However, there is no guideline for planning nature
conservation measures, and the efficiency of the realised protection measures are seldom
followed up by wildlife monitoring programmes.
Among wildlife protecting means, the game protecting ones (fences, passes) are the greatestinvestment in volume and in numbers as well. An obligatory part of concessioned motorwaysis the construction of wildlife fences. However, there are no studies so far about the habitatfragmentation effect of fences (made for safety purposes at first instance) in details. Stepsshould be made toward a more extended use of other measures decreasing collision risk (lightreflecting prisms, odours).
Concerning amphibian, reptile and small mammal passes the experience gathered is more thanenough in Hungary. However, compiling a suitable planning guideline is the task of the nearfuture.
A nationally and internationally unique spatial information program was initiated by theCOST programme. Experts attempted to create a model for the habitat fragmentation effect ofthe road network on the base of the existing digital databases. They drafted the road networkand nature conflict map the utilisation of which should be tested and improved in the near fu-ture.
The transportation policy of Hungary was developed in relation to the European integration.Transportation – and especially the development of motorway network and its links to the Eu-ropean network – will prospectively be a topic of outstanding importance during the acquisi-tion negotiations. It is of importance to represent the mature and approved (by the Governmentand by the Parliament) long-term policy plan defined by legislatory means during negotia-tions. The “Long-term development plan of the Hungarian motor- way–expressway network”is to be approved as law within the frame of the Regional Policy Plan of Hungary (OTT) underpreparation. The most important public road network development task regarding the promo-tion of the EU integration is the acceleration of motorway-expressway network construction.
Main transportation corridors, the development areas for the next 30 years are defined already.Their detailed study was launched and parallel with the detailed studies the first impact studieswere finished as well in some regions. On the base of the present report it would be worth
revising the older plans, schemes and policies or creating new ones for the purpose of
finding the best transport corridors and routes to serve nature conservation.
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COST 341
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